/* Copyright (c) 2012-2020, The Linux Foundation. All rights reserved. * Copyright (c) 2023 Qualcomm Innovation Center, Inc. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "adsp_err.h" #include #define TIMEOUT_MS 1000 #define RESET_COPP_ID 99 #define INVALID_COPP_ID 0xFF /* Used for inband payload copy, max size is 4k */ /* 3 is to account for module, instance & param ID in payload */ #define ADM_GET_PARAMETER_LENGTH (4096 - APR_HDR_SIZE - 3 * sizeof(uint32_t)) #define ULL_SUPPORTED_BITS_PER_SAMPLE 16 #define ULL_SUPPORTED_SAMPLE_RATE 48000 #ifndef CONFIG_DOLBY_DAP #undef DOLBY_ADM_COPP_TOPOLOGY_ID #define DOLBY_ADM_COPP_TOPOLOGY_ID 0xFFFFFFFE #endif #ifndef CONFIG_DOLBY_DS2 #undef DS2_ADM_COPP_TOPOLOGY_ID #define DS2_ADM_COPP_TOPOLOGY_ID 0xFFFFFFFF #endif /* ENUM for adm_status */ enum adm_cal_status { ADM_STATUS_CALIBRATION_REQUIRED = 0, ADM_STATUS_MAX, }; struct adm_copp { atomic_t id[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t cnt[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t topology[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t mode[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t stat[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t rate[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t bit_width[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t channels[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t app_type[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t acdb_id[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; wait_queue_head_t wait[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; wait_queue_head_t adm_delay_wait[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; atomic_t adm_delay_stat[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; uint32_t adm_delay[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; unsigned long adm_status[AFE_MAX_PORTS][MAX_COPPS_PER_PORT]; }; struct source_tracking_data { struct dma_buf *dma_buf; struct param_outband memmap; int apr_cmd_status; }; struct adm_ctl { void *apr; struct adm_copp copp; atomic_t matrix_map_stat; wait_queue_head_t matrix_map_wait; atomic_t adm_stat; wait_queue_head_t adm_wait; struct cal_type_data *cal_data[ADM_MAX_CAL_TYPES]; atomic_t mem_map_handles[ADM_MEM_MAP_INDEX_MAX]; atomic_t mem_map_index; struct param_outband outband_memmap; struct source_tracking_data sourceTrackingData; int set_custom_topology; int ec_ref_rx; int num_ec_ref_rx_chans; int ec_ref_rx_bit_width; int ec_ref_rx_sampling_rate; int ffecns_port_id; int native_mode; }; static struct adm_ctl this_adm; struct adm_multi_ch_map { bool set_channel_map; char channel_mapping[PCM_FORMAT_MAX_NUM_CHANNEL_V8]; }; #define ADM_MCH_MAP_IDX_PLAYBACK 0 #define ADM_MCH_MAP_IDX_REC 1 static struct adm_multi_ch_map multi_ch_maps[2] = { { false, {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} }, { false, {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} } }; static struct adm_multi_ch_map port_channel_map[AFE_MAX_PORTS]; static int adm_get_parameters[MAX_COPPS_PER_PORT * ADM_GET_PARAMETER_LENGTH]; static int adm_module_topo_list[MAX_COPPS_PER_PORT * ADM_GET_TOPO_MODULE_INSTANCE_LIST_LENGTH]; static struct mutex dts_srs_lock; void msm_dts_srs_acquire_lock(void) { mutex_lock(&dts_srs_lock); } void msm_dts_srs_release_lock(void) { mutex_unlock(&dts_srs_lock); } /** * adm_validate_and_get_port_index - * validate given port id * * @port_id: Port ID number * * Returns valid index on success or error on failure */ int adm_validate_and_get_port_index(int port_id) { int index; int ret; ret = q6audio_validate_port(port_id); if (ret < 0) { pr_err("%s: port validation failed id 0x%x ret %d\n", __func__, port_id, ret); return -EINVAL; } index = afe_get_port_index(port_id); if (index < 0 || index >= AFE_MAX_PORTS) { pr_err("%s: Invalid port idx %d port_id 0x%x\n", __func__, index, port_id); return -EINVAL; } pr_debug("%s: port_idx- %d\n", __func__, index); return index; } EXPORT_SYMBOL(adm_validate_and_get_port_index); /** * adm_get_default_copp_idx - * retrieve default copp_idx for given port * * @port_id: Port ID number * * Returns valid value on success or error on failure */ int adm_get_default_copp_idx(int port_id) { int port_idx = adm_validate_and_get_port_index(port_id), idx; if (port_idx < 0) { pr_err("%s: Invalid port id: 0x%x", __func__, port_id); return -EINVAL; } pr_debug("%s: port_idx:%d\n", __func__, port_idx); for (idx = 0; idx < MAX_COPPS_PER_PORT; idx++) { if (atomic_read(&this_adm.copp.id[port_idx][idx]) != RESET_COPP_ID) return idx; } return -EINVAL; } EXPORT_SYMBOL(adm_get_default_copp_idx); int adm_get_topology_for_port_from_copp_id(int port_id, int copp_id) { int port_idx = adm_validate_and_get_port_index(port_id), idx; if (port_idx < 0) { pr_err("%s: Invalid port id: 0x%x", __func__, port_id); return 0; } for (idx = 0; idx < MAX_COPPS_PER_PORT; idx++) if (atomic_read(&this_adm.copp.id[port_idx][idx]) == copp_id) return atomic_read(&this_adm.copp.topology[port_idx] [idx]); pr_err("%s: Invalid copp_id %d port_id 0x%x\n", __func__, copp_id, port_id); return 0; } /** * adm_get_topology_for_port_copp_idx - * retrieve topology of given port/copp_idx * * @port_id: Port ID number * @copp_idx: copp index of ADM copp * * Returns valid value on success or 0 on failure */ int adm_get_topology_for_port_copp_idx(int port_id, int copp_idx) { int port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid port: 0x%x copp id: 0x%x", __func__, port_id, copp_idx); return 0; } return atomic_read(&this_adm.copp.topology[port_idx][copp_idx]); } EXPORT_SYMBOL(adm_get_topology_for_port_copp_idx); int adm_get_indexes_from_copp_id(int copp_id, int *copp_idx, int *port_idx) { int p_idx, c_idx; for (p_idx = 0; p_idx < AFE_MAX_PORTS; p_idx++) { for (c_idx = 0; c_idx < MAX_COPPS_PER_PORT; c_idx++) { if (atomic_read(&this_adm.copp.id[p_idx][c_idx]) == copp_id) { if (copp_idx != NULL) *copp_idx = c_idx; if (port_idx != NULL) *port_idx = p_idx; return 0; } } } return -EINVAL; } static int adm_get_copp_id(int port_idx, int copp_idx) { pr_debug("%s: port_idx:%d copp_idx:%d\n", __func__, port_idx, copp_idx); if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_num: %d\n", __func__, copp_idx); return -EINVAL; } return atomic_read(&this_adm.copp.id[port_idx][copp_idx]); } static int adm_get_idx_if_copp_exists(int port_idx, int topology, int mode, int rate, int bit_width, int app_type) { int idx; pr_debug("%s: port_idx-%d, topology-0x%x, mode-%d, rate-%d, bit_width-%d\n", __func__, port_idx, topology, mode, rate, bit_width); for (idx = 0; idx < MAX_COPPS_PER_PORT; idx++) if ((topology == atomic_read(&this_adm.copp.topology[port_idx][idx])) && (mode == atomic_read(&this_adm.copp.mode[port_idx][idx])) && (rate == atomic_read(&this_adm.copp.rate[port_idx][idx])) && (bit_width == atomic_read(&this_adm.copp.bit_width[port_idx][idx])) && (app_type == atomic_read(&this_adm.copp.app_type[port_idx][idx]))) return idx; return -EINVAL; } static int adm_get_next_available_copp(int port_idx) { int idx; pr_debug("%s:\n", __func__); for (idx = 0; idx < MAX_COPPS_PER_PORT; idx++) { pr_debug("%s: copp_id:0x%x port_idx:%d idx:%d\n", __func__, atomic_read(&this_adm.copp.id[port_idx][idx]), port_idx, idx); if (atomic_read(&this_adm.copp.id[port_idx][idx]) == RESET_COPP_ID) break; } return idx; } /** * srs_trumedia_open - * command to set SRS trumedia open * * @port_id: Port ID number * @copp_idx: copp index of ADM copp * @srs_tech_id: SRS tech index * @srs_params: params pointer * * Returns 0 on success or error on failure */ int srs_trumedia_open(int port_id, int copp_idx, __s32 srs_tech_id, void *srs_params) { struct param_hdr_v3 param_hdr; struct mem_mapping_hdr mem_hdr; u32 total_param_size = 0; bool outband = false; int port_idx; int ret = 0; pr_debug("SRS - %s", __func__); memset(¶m_hdr, 0, sizeof(param_hdr)); memset(&mem_hdr, 0, sizeof(mem_hdr)); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id %#x\n", __func__, port_id); return -EINVAL; } param_hdr.module_id = SRS_TRUMEDIA_MODULE_ID; param_hdr.instance_id = INSTANCE_ID_0; switch (srs_tech_id) { case SRS_ID_GLOBAL: { param_hdr.param_id = SRS_TRUMEDIA_PARAMS; param_hdr.param_size = sizeof(struct srs_trumedia_params_GLOBAL); break; } case SRS_ID_WOWHD: { param_hdr.param_id = SRS_TRUMEDIA_PARAMS_WOWHD; param_hdr.param_size = sizeof(struct srs_trumedia_params_WOWHD); break; } case SRS_ID_CSHP: { param_hdr.param_id = SRS_TRUMEDIA_PARAMS_CSHP; param_hdr.param_size = sizeof(struct srs_trumedia_params_CSHP); break; } case SRS_ID_HPF: { param_hdr.param_id = SRS_TRUMEDIA_PARAMS_HPF; param_hdr.param_size = sizeof(struct srs_trumedia_params_HPF); break; } case SRS_ID_AEQ: { u8 *update_params_ptr = (u8 *) this_adm.outband_memmap.kvaddr; outband = true; if (update_params_ptr == NULL) { pr_err("ADM_SRS_TRUMEDIA - %s: null memmap for AEQ params\n", __func__); ret = -EINVAL; goto fail_cmd; } param_hdr.param_id = SRS_TRUMEDIA_PARAMS_AEQ; param_hdr.param_size = sizeof(struct srs_trumedia_params_AEQ); ret = q6common_pack_pp_params(update_params_ptr, ¶m_hdr, srs_params, &total_param_size); if (ret) { pr_err("%s: Failed to pack param header and data, error %d\n", __func__, ret); goto fail_cmd; } break; } case SRS_ID_HL: { param_hdr.param_id = SRS_TRUMEDIA_PARAMS_HL; param_hdr.param_size = sizeof(struct srs_trumedia_params_HL); break; } case SRS_ID_GEQ: { param_hdr.param_id = SRS_TRUMEDIA_PARAMS_GEQ; param_hdr.param_size = sizeof(struct srs_trumedia_params_GEQ); break; } default: goto fail_cmd; } if (outband && this_adm.outband_memmap.paddr) { mem_hdr.data_payload_addr_lsw = lower_32_bits(this_adm.outband_memmap.paddr); mem_hdr.data_payload_addr_msw = msm_audio_populate_upper_32_bits( this_adm.outband_memmap.paddr); mem_hdr.mem_map_handle = atomic_read( &this_adm.mem_map_handles[ADM_SRS_TRUMEDIA]); ret = adm_set_pp_params(port_id, copp_idx, &mem_hdr, NULL, total_param_size); } else { ret = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (u8 *) srs_params); } if (ret < 0) pr_err("SRS - %s: ADM enable for port %d failed\n", __func__, port_id); fail_cmd: return ret; } EXPORT_SYMBOL(srs_trumedia_open); static int adm_populate_channel_weight(u16 *ptr, struct msm_pcm_channel_mixer *ch_mixer, int channel_index) { u16 i, j, start_index = 0; if (channel_index > ch_mixer->output_channel) { pr_err("%s: channel index %d is larger than output_channel %d\n", __func__, channel_index, ch_mixer->output_channel); return -EINVAL; } for (i = 0; i < ch_mixer->output_channel; i++) { pr_debug("%s: weight for output %d:", __func__, i); for (j = 0; j < ADM_MAX_CHANNELS; j++) pr_debug(" %d", ch_mixer->channel_weight[i][j]); pr_debug("\n"); } for (i = 0; i < channel_index; ++i) start_index += ch_mixer->input_channels[i]; for (i = 0; i < ch_mixer->output_channel; ++i) { for (j = start_index; j < start_index + ch_mixer->input_channels[channel_index]; j++) { *ptr = ch_mixer->channel_weight[i][j]; pr_debug("%s: ptr[%d][%d] = %d\n", __func__, i, j, *ptr); ptr++; } } return 0; } /* * adm_programable_channel_mixer * * Receives port_id, copp_idx, session_id, session_type, ch_mixer * and channel_index to send ADM command to mix COPP data. * * port_id - Passed value, port_id for which backend is wanted * copp_idx - Passed value, copp_idx for which COPP is wanted * session_id - Passed value, session_id for which session is needed * session_type - Passed value, session_type for RX or TX * ch_mixer - Passed value, ch_mixer for which channel mixer config is needed * channel_index - Passed value, channel_index for which channel is needed */ int adm_programable_channel_mixer(int port_id, int copp_idx, int session_id, int session_type, struct msm_pcm_channel_mixer *ch_mixer, int channel_index) { struct adm_cmd_set_pspd_mtmx_strtr_params_v5 *adm_params = NULL; struct param_hdr_v1 data_v5; int ret = 0, port_idx, sz = 0, param_size = 0; u16 *adm_pspd_params; u16 *ptr; int index = 0; pr_debug("%s: port_id = %d\n", __func__, port_id); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id %#x\n", __func__, port_id); return -EINVAL; } /* * First 8 bytes are 4 bytes as rule number, 2 bytes as output * channel and 2 bytes as input channel. * 2 * ch_mixer->output_channel means output channel mapping. * 2 * ch_mixer->input_channels[channel_index]) means input * channel mapping. * 2 * ch_mixer->input_channels[channel_index] * * ch_mixer->output_channel) means the channel mixer weighting * coefficients. * param_size needs to be a multiple of 4 bytes. */ param_size = 2 * (4 + ch_mixer->output_channel + ch_mixer->input_channels[channel_index] + ch_mixer->input_channels[channel_index] * ch_mixer->output_channel); param_size = roundup(param_size, 4); sz = sizeof(struct adm_cmd_set_pspd_mtmx_strtr_params_v5) + sizeof(struct default_chmixer_param_id_coeff) + sizeof(struct param_hdr_v1) + param_size; pr_debug("%s: sz = %d\n", __func__, sz); adm_params = kzalloc(sz, GFP_KERNEL); if (!adm_params) return -ENOMEM; adm_params->payload_addr_lsw = 0; adm_params->payload_addr_msw = 0; adm_params->mem_map_handle = 0; adm_params->direction = session_type; adm_params->sessionid = session_id; pr_debug("%s: copp_id = %d, session id %d\n", __func__, atomic_read(&this_adm.copp.id[port_idx][copp_idx]), session_id); adm_params->deviceid = atomic_read( &this_adm.copp.id[port_idx][copp_idx]); adm_params->reserved = 0; /* * This module is internal to ADSP and cannot be configured with * an instance id */ data_v5.module_id = MTMX_MODULE_ID_DEFAULT_CHMIXER; data_v5.param_id = DEFAULT_CHMIXER_PARAM_ID_COEFF; data_v5.reserved = 0; data_v5.param_size = param_size; adm_params->payload_size = sizeof(struct default_chmixer_param_id_coeff) + sizeof(struct param_hdr_v1) + data_v5.param_size; adm_pspd_params = (u16 *)((u8 *)adm_params + sizeof(struct adm_cmd_set_pspd_mtmx_strtr_params_v5)); memcpy(adm_pspd_params, &data_v5, sizeof(data_v5)); adm_pspd_params = (u16 *)((u8 *)adm_params + sizeof(struct adm_cmd_set_pspd_mtmx_strtr_params_v5) + sizeof(data_v5)); adm_pspd_params[0] = ch_mixer->rule; adm_pspd_params[2] = ch_mixer->output_channel; adm_pspd_params[3] = ch_mixer->input_channels[channel_index]; index = 4; if (ch_mixer->output_channel == 1) { adm_pspd_params[index] = PCM_CHANNEL_FC; } else if (ch_mixer->output_channel == 2) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; } else if (ch_mixer->output_channel == 3) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_FC; } else if (ch_mixer->output_channel == 4) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_LS; adm_pspd_params[index + 3] = PCM_CHANNEL_RS; } else if (ch_mixer->output_channel == 5) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_FC; adm_pspd_params[index + 3] = PCM_CHANNEL_LS; adm_pspd_params[index + 4] = PCM_CHANNEL_RS; } else if (ch_mixer->output_channel == 6) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_LFE; adm_pspd_params[index + 3] = PCM_CHANNEL_FC; adm_pspd_params[index + 4] = PCM_CHANNEL_LS; adm_pspd_params[index + 5] = PCM_CHANNEL_RS; } else if (ch_mixer->output_channel == 8) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_LFE; adm_pspd_params[index + 3] = PCM_CHANNEL_FC; adm_pspd_params[index + 4] = PCM_CHANNEL_LS; adm_pspd_params[index + 5] = PCM_CHANNEL_RS; adm_pspd_params[index + 6] = PCM_CHANNEL_LB; adm_pspd_params[index + 7] = PCM_CHANNEL_RB; } index = index + ch_mixer->output_channel; if (ch_mixer->input_channels[channel_index] == 1) { adm_pspd_params[index] = PCM_CHANNEL_FC; } else if (ch_mixer->input_channels[channel_index] == 2) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; } else if (ch_mixer->input_channels[channel_index] == 3) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_FC; } else if (ch_mixer->input_channels[channel_index] == 4) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_LS; adm_pspd_params[index + 3] = PCM_CHANNEL_RS; } else if (ch_mixer->input_channels[channel_index] == 5) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_FC; adm_pspd_params[index + 3] = PCM_CHANNEL_LS; adm_pspd_params[index + 4] = PCM_CHANNEL_RS; } else if (ch_mixer->input_channels[channel_index] == 6) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_LFE; adm_pspd_params[index + 3] = PCM_CHANNEL_FC; adm_pspd_params[index + 4] = PCM_CHANNEL_LS; adm_pspd_params[index + 5] = PCM_CHANNEL_RS; } else if (ch_mixer->input_channels[channel_index] == 8) { adm_pspd_params[index] = PCM_CHANNEL_FL; adm_pspd_params[index + 1] = PCM_CHANNEL_FR; adm_pspd_params[index + 2] = PCM_CHANNEL_LFE; adm_pspd_params[index + 3] = PCM_CHANNEL_FC; adm_pspd_params[index + 4] = PCM_CHANNEL_LS; adm_pspd_params[index + 5] = PCM_CHANNEL_RS; adm_pspd_params[index + 6] = PCM_CHANNEL_LB; adm_pspd_params[index + 7] = PCM_CHANNEL_RB; } index = index + ch_mixer->input_channels[channel_index]; ret = adm_populate_channel_weight(&adm_pspd_params[index], ch_mixer, channel_index); if (ret) { pr_err("%s: fail to get channel weight with error %d\n", __func__, ret); goto fail_cmd; } adm_params->hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); adm_params->hdr.src_svc = APR_SVC_ADM; adm_params->hdr.src_domain = APR_DOMAIN_APPS; adm_params->hdr.src_port = port_id; adm_params->hdr.dest_svc = APR_SVC_ADM; adm_params->hdr.dest_domain = APR_DOMAIN_ADSP; adm_params->hdr.dest_port = atomic_read(&this_adm.copp.id[port_idx][copp_idx]); adm_params->hdr.token = port_idx << 16 | copp_idx; adm_params->hdr.opcode = ADM_CMD_SET_PSPD_MTMX_STRTR_PARAMS_V5; adm_params->hdr.pkt_size = sz; adm_params->payload_addr_lsw = 0; adm_params->payload_addr_msw = 0; adm_params->mem_map_handle = 0; adm_params->reserved = 0; ptr = (u16 *)adm_params; for (index = 0; index < (sz / 2); index++) pr_debug("%s: adm_params[%d] = 0x%x\n", __func__, index, (unsigned int)ptr[index]); atomic_set(&this_adm.copp.stat[port_idx][copp_idx], 0); ret = apr_send_pkt(this_adm.apr, (uint32_t *)adm_params); if (ret < 0) { pr_err("%s: Set params failed port %d rc %d\n", __func__, port_id, ret); ret = -EINVAL; goto fail_cmd; } ret = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read( &this_adm.copp.stat[port_idx][copp_idx]) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: set params timed out port = %d\n", __func__, port_id); ret = -ETIMEDOUT; goto fail_cmd; } ret = 0; fail_cmd: kfree(adm_params); return ret; } EXPORT_SYMBOL(adm_programable_channel_mixer); /** * adm_set_stereo_to_custom_stereo - * command to update custom stereo * * @port_id: Port ID number * @copp_idx: copp index of ADM copp * @session_id: session id to be updated * @params: params pointer * @param_length: length of params * * Returns 0 on success or error on failure */ int adm_set_stereo_to_custom_stereo(int port_id, int copp_idx, unsigned int session_id, char *params, uint32_t params_length) { struct adm_cmd_set_pspd_mtmx_strtr_params_v5 *adm_params = NULL; int sz, rc = 0, port_idx; pr_debug("%s:\n", __func__); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return -EINVAL; } sz = sizeof(struct adm_cmd_set_pspd_mtmx_strtr_params_v5) + params_length; adm_params = kzalloc(sz, GFP_KERNEL); if (!adm_params) { pr_err("%s, adm params memory alloc failed\n", __func__); return -ENOMEM; } memcpy(((u8 *)adm_params + sizeof(struct adm_cmd_set_pspd_mtmx_strtr_params_v5)), params, params_length); adm_params->hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); adm_params->hdr.pkt_size = sz; adm_params->hdr.src_svc = APR_SVC_ADM; adm_params->hdr.src_domain = APR_DOMAIN_APPS; adm_params->hdr.src_port = port_id; adm_params->hdr.dest_svc = APR_SVC_ADM; adm_params->hdr.dest_domain = APR_DOMAIN_ADSP; adm_params->hdr.dest_port = 0; /* Ignored */; adm_params->hdr.token = port_idx << 16 | copp_idx; adm_params->hdr.opcode = ADM_CMD_SET_PSPD_MTMX_STRTR_PARAMS_V5; adm_params->payload_addr_lsw = 0; adm_params->payload_addr_msw = 0; adm_params->mem_map_handle = 0; adm_params->payload_size = params_length; /* direction RX as 0 */ adm_params->direction = ADM_MATRIX_ID_AUDIO_RX; /* session id for this cmd to be applied on */ adm_params->sessionid = session_id; adm_params->deviceid = atomic_read(&this_adm.copp.id[port_idx][copp_idx]); adm_params->reserved = 0; pr_debug("%s: deviceid %d, session_id %d, src_port %d, dest_port %d\n", __func__, adm_params->deviceid, adm_params->sessionid, adm_params->hdr.src_port, adm_params->hdr.dest_port); atomic_set(&this_adm.copp.stat[port_idx][copp_idx], -1); rc = apr_send_pkt(this_adm.apr, (uint32_t *)adm_params); if (rc < 0) { pr_err("%s: Set params failed port = 0x%x rc %d\n", __func__, port_id, rc); rc = -EINVAL; goto set_stereo_to_custom_stereo_return; } /* Wait for the callback */ rc = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!rc) { pr_err("%s: Set params timed out port = 0x%x\n", __func__, port_id); rc = -EINVAL; goto set_stereo_to_custom_stereo_return; } else if (atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str(atomic_read( &this_adm.copp.stat [port_idx][copp_idx]))); rc = adsp_err_get_lnx_err_code( atomic_read(&this_adm.copp.stat [port_idx][copp_idx])); goto set_stereo_to_custom_stereo_return; } rc = 0; set_stereo_to_custom_stereo_return: kfree(adm_params); return rc; } EXPORT_SYMBOL(adm_set_stereo_to_custom_stereo); /* * adm_set_custom_chmix_cfg: * Set the custom channel mixer configuration for ADM * * @port_id: Backend port id * @copp_idx: ADM copp index * @session_id: ID of the requesting session * @params: Expected packaged params for channel mixer * @params_length: Length of the params to be set * @direction: RX or TX direction * @stream_type: Audio or Listen stream type */ int adm_set_custom_chmix_cfg(int port_id, int copp_idx, unsigned int session_id, char *params, uint32_t params_length, int direction, int stream_type) { struct adm_cmd_set_pspd_mtmx_strtr_params_v6 *adm_params = NULL; int sz, rc = 0, port_idx; port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return -EINVAL; } sz = sizeof(struct adm_cmd_set_pspd_mtmx_strtr_params_v6) + params_length; adm_params = kzalloc(sz, GFP_KERNEL); if (!adm_params) { pr_err("%s, adm params memory alloc failed\n", __func__); return -ENOMEM; } memcpy(((u8 *)adm_params + sizeof(struct adm_cmd_set_pspd_mtmx_strtr_params_v6)), params, params_length); adm_params->hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); adm_params->hdr.pkt_size = sz; adm_params->hdr.src_svc = APR_SVC_ADM; adm_params->hdr.src_domain = APR_DOMAIN_APPS; adm_params->hdr.src_port = port_id; adm_params->hdr.dest_svc = APR_SVC_ADM; adm_params->hdr.dest_domain = APR_DOMAIN_ADSP; adm_params->hdr.dest_port = 0; /* Ignored */; adm_params->hdr.token = port_idx << 16 | copp_idx; adm_params->hdr.opcode = ADM_CMD_SET_PSPD_MTMX_STRTR_PARAMS_V6; adm_params->payload_addr_lsw = 0; adm_params->payload_addr_msw = 0; adm_params->mem_map_handle = 0; adm_params->payload_size = params_length; adm_params->direction = direction; /* session id for this cmd to be applied on */ adm_params->sessionid = session_id; adm_params->deviceid = atomic_read(&this_adm.copp.id[port_idx][copp_idx]); /* connecting stream type i.e. lsm or asm */ adm_params->stream_type = stream_type; pr_debug("%s: deviceid %d, session_id %d, src_port %d, dest_port %d\n", __func__, adm_params->deviceid, adm_params->sessionid, adm_params->hdr.src_port, adm_params->hdr.dest_port); atomic_set(&this_adm.copp.stat[port_idx][copp_idx], -1); rc = apr_send_pkt(this_adm.apr, (uint32_t *)adm_params); if (rc < 0) { pr_err("%s: Set params failed port = 0x%x rc %d\n", __func__, port_id, rc); rc = -EINVAL; goto exit; } /* Wait for the callback */ rc = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(&this_adm.copp.stat [port_idx][copp_idx]), msecs_to_jiffies(TIMEOUT_MS)); if (!rc) { pr_err("%s: Set params timed out port = 0x%x\n", __func__, port_id); rc = -EINVAL; goto exit; } else if (atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str(atomic_read( &this_adm.copp.stat [port_idx][copp_idx]))); rc = adsp_err_get_lnx_err_code( atomic_read(&this_adm.copp.stat [port_idx][copp_idx])); goto exit; } rc = 0; exit: kfree(adm_params); return rc; } EXPORT_SYMBOL(adm_set_custom_chmix_cfg); /* * With pre-packed data, only the opcode differes from V5 and V6. * Use q6common_pack_pp_params to pack the data correctly. */ int adm_set_pp_params(int port_id, int copp_idx, struct mem_mapping_hdr *mem_hdr, u8 *param_data, u32 param_size) { struct adm_cmd_set_pp_params *adm_set_params = NULL; int size = 0; int port_idx = 0; atomic_t *copp_stat = NULL; int ret = 0; port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0 || port_idx >= AFE_MAX_PORTS) { pr_err("%s: Invalid port_idx 0x%x\n", __func__, port_idx); return -EINVAL; } else if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_idx 0x%x\n", __func__, copp_idx); return -EINVAL; } /* Only add params_size in inband case */ size = sizeof(struct adm_cmd_set_pp_params); if (param_data != NULL) size += param_size; adm_set_params = kzalloc(size, GFP_KERNEL); if (!adm_set_params) return -ENOMEM; adm_set_params->apr_hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); adm_set_params->apr_hdr.pkt_size = size; adm_set_params->apr_hdr.src_svc = APR_SVC_ADM; adm_set_params->apr_hdr.src_domain = APR_DOMAIN_APPS; adm_set_params->apr_hdr.src_port = port_id; adm_set_params->apr_hdr.dest_svc = APR_SVC_ADM; adm_set_params->apr_hdr.dest_domain = APR_DOMAIN_ADSP; adm_set_params->apr_hdr.dest_port = atomic_read(&this_adm.copp.id[port_idx][copp_idx]); adm_set_params->apr_hdr.token = port_idx << 16 | copp_idx; if (q6common_is_instance_id_supported()) adm_set_params->apr_hdr.opcode = ADM_CMD_SET_PP_PARAMS_V6; else adm_set_params->apr_hdr.opcode = ADM_CMD_SET_PP_PARAMS_V5; adm_set_params->payload_size = param_size; if (mem_hdr != NULL) { /* Out of Band Case */ adm_set_params->mem_hdr = *mem_hdr; } else if (param_data != NULL) { /* * In band case. Parameter data must be pre-packed with its * header before calling this function. Use * q6common_pack_pp_params to pack parameter data and header * correctly. */ memcpy(&adm_set_params->param_data, param_data, param_size); } else { pr_err("%s: Received NULL pointers for both memory header and param data\n", __func__); ret = -EINVAL; goto done; } copp_stat = &this_adm.copp.stat[port_idx][copp_idx]; atomic_set(copp_stat, -1); ret = apr_send_pkt(this_adm.apr, (uint32_t *) adm_set_params); if (ret < 0) { pr_err("%s: Set params APR send failed port = 0x%x ret %d\n", __func__, port_id, ret); goto done; } ret = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(copp_stat) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: Set params timed out port = 0x%x\n", __func__, port_id); ret = -ETIMEDOUT; goto done; } if (atomic_read(copp_stat) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str(atomic_read(copp_stat))); ret = adsp_err_get_lnx_err_code(atomic_read(copp_stat)); goto done; } ret = 0; done: kfree(adm_set_params); return ret; } EXPORT_SYMBOL(adm_set_pp_params); int adm_pack_and_set_one_pp_param(int port_id, int copp_idx, struct param_hdr_v3 param_hdr, u8 *param_data) { u8 *packed_data = NULL; u32 total_size = 0; int ret = 0; total_size = sizeof(union param_hdrs) + param_hdr.param_size; packed_data = kzalloc(total_size, GFP_KERNEL); if (!packed_data) return -ENOMEM; ret = q6common_pack_pp_params(packed_data, ¶m_hdr, param_data, &total_size); if (ret) { pr_err("%s: Failed to pack parameter data, error %d\n", __func__, ret); goto done; } ret = adm_set_pp_params(port_id, copp_idx, NULL, packed_data, total_size); if (ret) pr_err("%s: Failed to set parameter data, error %d\n", __func__, ret); done: kfree(packed_data); return ret; } EXPORT_SYMBOL(adm_pack_and_set_one_pp_param); /* * Only one parameter can be requested at a time. Therefore, packing and sending * the request can be handled locally. */ int adm_get_pp_params(int port_id, int copp_idx, uint32_t client_id, struct mem_mapping_hdr *mem_hdr, struct param_hdr_v3 *param_hdr, u8 *returned_param_data) { struct adm_cmd_get_pp_params adm_get_params; int total_size = 0; int get_param_array_sz = ARRAY_SIZE(adm_get_parameters); int returned_param_size = 0; int returned_param_size_in_bytes = 0; int port_idx = 0; int idx = 0; atomic_t *copp_stat = NULL; int ret = 0; if (param_hdr == NULL) { pr_err("%s: Received NULL pointer for parameter header\n", __func__); return -EINVAL; } port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0 || port_idx >= AFE_MAX_PORTS) { pr_err("%s: Invalid port_idx 0x%x\n", __func__, port_idx); return -EINVAL; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_idx 0x%x\n", __func__, copp_idx); return -EINVAL; } memset(&adm_get_params, 0, sizeof(adm_get_params)); if (mem_hdr != NULL) adm_get_params.mem_hdr = *mem_hdr; q6common_pack_pp_params((u8 *) &adm_get_params.param_hdr, param_hdr, NULL, &total_size); /* Pack APR header after filling body so total_size has correct value */ adm_get_params.apr_hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); adm_get_params.apr_hdr.pkt_size = sizeof(adm_get_params); adm_get_params.apr_hdr.src_svc = APR_SVC_ADM; adm_get_params.apr_hdr.src_domain = APR_DOMAIN_APPS; adm_get_params.apr_hdr.src_port = port_id; adm_get_params.apr_hdr.dest_svc = APR_SVC_ADM; adm_get_params.apr_hdr.dest_domain = APR_DOMAIN_ADSP; adm_get_params.apr_hdr.dest_port = atomic_read(&this_adm.copp.id[port_idx][copp_idx]); adm_get_params.apr_hdr.token = port_idx << 16 | client_id << 8 | copp_idx; if (q6common_is_instance_id_supported()) adm_get_params.apr_hdr.opcode = ADM_CMD_GET_PP_PARAMS_V6; else adm_get_params.apr_hdr.opcode = ADM_CMD_GET_PP_PARAMS_V5; copp_stat = &this_adm.copp.stat[port_idx][copp_idx]; atomic_set(copp_stat, -1); ret = apr_send_pkt(this_adm.apr, (uint32_t *) &adm_get_params); if (ret < 0) { pr_err("%s: Get params APR send failed port = 0x%x ret %d\n", __func__, port_id, ret); ret = -EINVAL; goto done; } ret = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(copp_stat) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: Get params timed out port = 0x%x\n", __func__, port_id); ret = -ETIMEDOUT; goto done; } if (atomic_read(copp_stat) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str(atomic_read(copp_stat))); ret = adsp_err_get_lnx_err_code(atomic_read(copp_stat)); goto done; } ret = 0; /* Copy data to caller if sent in band */ if (!returned_param_data) { pr_debug("%s: Received NULL pointer for param destination, not copying payload\n", __func__); return 0; } idx = ADM_GET_PARAMETER_LENGTH * copp_idx; returned_param_size = adm_get_parameters[idx]; if (returned_param_size < 0 || returned_param_size + idx + 1 > get_param_array_sz) { pr_err("%s: Invalid parameter size %d\n", __func__, returned_param_size); return -EINVAL; } returned_param_size_in_bytes = returned_param_size * sizeof(uint32_t); if (param_hdr->param_size < returned_param_size_in_bytes) { pr_err("%s: Provided buffer is not big enough, provided buffer size(%d) size needed(%d)\n", __func__, param_hdr->param_size, returned_param_size_in_bytes); return -EINVAL; } memcpy(returned_param_data, &adm_get_parameters[idx + 1], returned_param_size_in_bytes); done: return ret; } EXPORT_SYMBOL(adm_get_pp_params); int adm_get_pp_topo_module_list_v2(int port_id, int copp_idx, int32_t param_length, int32_t *returned_params) { struct adm_cmd_get_pp_topo_module_list adm_get_module_list; bool iid_supported = q6common_is_instance_id_supported(); int *topo_list; int num_modules = 0; int list_size = 0; int port_idx, idx; int i = 0; atomic_t *copp_stat = NULL; int ret = 0; pr_debug("%s : port_id %x", __func__, port_id); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return -EINVAL; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_num: %d\n", __func__, copp_idx); return -EINVAL; } memset(&adm_get_module_list, 0, sizeof(adm_get_module_list)); adm_get_module_list.apr_hdr.pkt_size = sizeof(adm_get_module_list); adm_get_module_list.apr_hdr.src_svc = APR_SVC_ADM; adm_get_module_list.apr_hdr.src_domain = APR_DOMAIN_APPS; adm_get_module_list.apr_hdr.src_port = port_id; adm_get_module_list.apr_hdr.dest_svc = APR_SVC_ADM; adm_get_module_list.apr_hdr.dest_domain = APR_DOMAIN_ADSP; adm_get_module_list.apr_hdr.dest_port = atomic_read(&this_adm.copp.id[port_idx][copp_idx]); adm_get_module_list.apr_hdr.token = port_idx << 16 | copp_idx; /* * Out of band functionality is not currently utilized. * Assume in band. */ if (iid_supported) { adm_get_module_list.apr_hdr.opcode = ADM_CMD_GET_PP_TOPO_MODULE_LIST_V2; adm_get_module_list.param_max_size = param_length; } else { adm_get_module_list.apr_hdr.opcode = ADM_CMD_GET_PP_TOPO_MODULE_LIST; if (param_length > U16_MAX) { pr_err("%s: Invalid param length for V1 %d\n", __func__, param_length); return -EINVAL; } adm_get_module_list.param_max_size = param_length << 16; } copp_stat = &this_adm.copp.stat[port_idx][copp_idx]; atomic_set(copp_stat, -1); ret = apr_send_pkt(this_adm.apr, (uint32_t *) &adm_get_module_list); if (ret < 0) { pr_err("%s: APR send pkt failed for port_id: 0x%x failed ret %d\n", __func__, port_id, ret); ret = -EINVAL; goto done; } ret = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(copp_stat) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: Timeout for port_id: 0x%x\n", __func__, port_id); ret = -ETIMEDOUT; goto done; } if (atomic_read(copp_stat) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str(atomic_read(copp_stat))); ret = adsp_err_get_lnx_err_code(atomic_read(copp_stat)); goto done; } ret = 0; if (returned_params) { /* * When processing ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST IID is * added since it is not present. Therefore, there is no need to * do anything different if IID is not supported here as it is * already taken care of. */ idx = ADM_GET_TOPO_MODULE_INSTANCE_LIST_LENGTH * copp_idx; num_modules = adm_module_topo_list[idx]; if (num_modules < 0 || num_modules > MAX_MODULES_IN_TOPO) { pr_err("%s: Invalid number of modules returned %d\n", __func__, num_modules); return -EINVAL; } list_size = num_modules * sizeof(struct module_instance_info); if (param_length < list_size) { pr_err("%s: Provided buffer not big enough to hold module-instance list, provided size %d, needed size %d\n", __func__, param_length, list_size); return -EINVAL; } topo_list = (int32_t *) (&adm_module_topo_list[idx]); memcpy(returned_params, topo_list, list_size); for (i = 1; i <= num_modules; i += 2) { pr_debug("module = 0x%x instance = 0x%x\n", returned_params[i], returned_params[i + 1]); } } done: return ret; } EXPORT_SYMBOL(adm_get_pp_topo_module_list_v2); static void adm_callback_debug_print(struct apr_client_data *data) { uint32_t *payload; payload = data->payload; if (data->payload_size >= 8) pr_debug("%s: code = 0x%x PL#0[0x%x], PL#1[0x%x], size = %d\n", __func__, data->opcode, payload[0], payload[1], data->payload_size); else if (data->payload_size >= 4) pr_debug("%s: code = 0x%x PL#0[0x%x], size = %d\n", __func__, data->opcode, payload[0], data->payload_size); else pr_debug("%s: code = 0x%x, size = %d\n", __func__, data->opcode, data->payload_size); } /** * adm_set_multi_ch_map - * Update multi channel map info * * @channel_map: pointer with channel map info * @path: direction or ADM path type * * Returns 0 on success or error on failure */ int adm_set_multi_ch_map(char *channel_map, int path) { int idx; if (path == ADM_PATH_PLAYBACK) { idx = ADM_MCH_MAP_IDX_PLAYBACK; } else if (path == ADM_PATH_LIVE_REC) { idx = ADM_MCH_MAP_IDX_REC; } else { pr_err("%s: invalid attempt to set path %d\n", __func__, path); return -EINVAL; } memcpy(multi_ch_maps[idx].channel_mapping, channel_map, PCM_FORMAT_MAX_NUM_CHANNEL_V8); multi_ch_maps[idx].set_channel_map = true; return 0; } EXPORT_SYMBOL(adm_set_multi_ch_map); /** * adm_get_multi_ch_map - * Retrieves multi channel map info * * @channel_map: pointer to be updated with channel map * @path: direction or ADM path type * * Returns 0 on success or error on failure */ int adm_get_multi_ch_map(char *channel_map, int path) { int idx; if (path == ADM_PATH_PLAYBACK) { idx = ADM_MCH_MAP_IDX_PLAYBACK; } else if (path == ADM_PATH_LIVE_REC) { idx = ADM_MCH_MAP_IDX_REC; } else { pr_err("%s: invalid attempt to get path %d\n", __func__, path); return -EINVAL; } if (multi_ch_maps[idx].set_channel_map) { memcpy(channel_map, multi_ch_maps[idx].channel_mapping, PCM_FORMAT_MAX_NUM_CHANNEL_V8); } return 0; } EXPORT_SYMBOL(adm_get_multi_ch_map); /** * adm_set_port_multi_ch_map - * Update port specific channel map info * * @channel_map: pointer with channel map info * @port_id: port for which chmap is set */ void adm_set_port_multi_ch_map(char *channel_map, int port_id) { int port_idx; port_id = q6audio_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return; } memcpy(port_channel_map[port_idx].channel_mapping, channel_map, PCM_FORMAT_MAX_NUM_CHANNEL_V8); port_channel_map[port_idx].set_channel_map = true; } EXPORT_SYMBOL(adm_set_port_multi_ch_map); static int adm_process_get_param_response(u32 opcode, u32 idx, u32 *payload, u32 payload_size) { struct adm_cmd_rsp_get_pp_params_v5 *v5_rsp = NULL; struct adm_cmd_rsp_get_pp_params_v6 *v6_rsp = NULL; u32 *param_data = NULL; int data_size = 0; int struct_size = 0; if (payload == NULL) { pr_err("%s: Payload is NULL\n", __func__); return -EINVAL; } switch (opcode) { case ADM_CMDRSP_GET_PP_PARAMS_V5: struct_size = sizeof(struct adm_cmd_rsp_get_pp_params_v5); if (payload_size < struct_size) { pr_err("%s: payload size %d < expected size %d\n", __func__, payload_size, struct_size); break; } v5_rsp = (struct adm_cmd_rsp_get_pp_params_v5 *) payload; data_size = v5_rsp->param_hdr.param_size; param_data = v5_rsp->param_data; break; case ADM_CMDRSP_GET_PP_PARAMS_V6: struct_size = sizeof(struct adm_cmd_rsp_get_pp_params_v6); if (payload_size < struct_size) { pr_err("%s: payload size %d < expected size %d\n", __func__, payload_size, struct_size); break; } v6_rsp = (struct adm_cmd_rsp_get_pp_params_v6 *) payload; data_size = v6_rsp->param_hdr.param_size; param_data = v6_rsp->param_data; break; default: pr_err("%s: Invalid opcode %d\n", __func__, opcode); return -EINVAL; } /* * Just store the returned parameter data, not the header. The calling * function is expected to know what it asked for. Therefore, there is * no difference between V5 and V6. */ if ((payload_size >= struct_size + data_size) && (ARRAY_SIZE(adm_get_parameters) > idx) && (ARRAY_SIZE(adm_get_parameters) > idx + 1 + data_size)) { pr_debug("%s: Received parameter data in band\n", __func__); /* * data_size is expressed in number of bytes, store in number of * ints */ adm_get_parameters[idx] = data_size / sizeof(*adm_get_parameters); pr_debug("%s: GET_PP PARAM: received parameter length: 0x%x\n", __func__, adm_get_parameters[idx]); /* store params after param_size */ memcpy(&adm_get_parameters[idx + 1], param_data, data_size); } else if (payload_size == sizeof(uint32_t)) { adm_get_parameters[idx] = -1; pr_debug("%s: Out of band case, setting size to %d\n", __func__, adm_get_parameters[idx]); } else { pr_err("%s: Invalid parameter combination, payload_size %d, idx %d\n", __func__, payload_size, idx); return -EINVAL; } return 0; } static int adm_process_get_topo_list_response(u32 opcode, int copp_idx, u32 num_modules, u32 *payload, u32 payload_size) { u32 *fill_list = NULL; int idx = 0; int i = 0; int j = 0; if (payload == NULL) { pr_err("%s: Payload is NULL\n", __func__); return -EINVAL; } else if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid COPP index %d\n", __func__, copp_idx); return -EINVAL; } idx = ADM_GET_TOPO_MODULE_INSTANCE_LIST_LENGTH * copp_idx; fill_list = adm_module_topo_list + idx; *fill_list++ = num_modules; for (i = 0; i < num_modules; i++) { if (j > payload_size / sizeof(u32)) { pr_err("%s: Invalid number of modules specified %d\n", __func__, num_modules); return -EINVAL; } /* store module ID */ *fill_list++ = payload[j]; j++; switch (opcode) { case ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST_V2: /* store instance ID */ *fill_list++ = payload[j]; j++; break; case ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST: /* Insert IID 0 when repacking */ *fill_list++ = INSTANCE_ID_0; break; default: pr_err("%s: Invalid opcode %d\n", __func__, opcode); return -EINVAL; } } return 0; } static void adm_reset_data(void) { int i, j; apr_reset(this_adm.apr); for (i = 0; i < AFE_MAX_PORTS; i++) { for (j = 0; j < MAX_COPPS_PER_PORT; j++) { atomic_set(&this_adm.copp.id[i][j], RESET_COPP_ID); atomic_set(&this_adm.copp.cnt[i][j], 0); atomic_set( &this_adm.copp.topology[i][j], 0); atomic_set(&this_adm.copp.mode[i][j], 0); atomic_set(&this_adm.copp.stat[i][j], 0); atomic_set(&this_adm.copp.rate[i][j], 0); atomic_set( &this_adm.copp.channels[i][j], 0); atomic_set( &this_adm.copp.bit_width[i][j], 0); atomic_set( &this_adm.copp.app_type[i][j], 0); atomic_set( &this_adm.copp.acdb_id[i][j], 0); this_adm.copp.adm_status[i][j] = ADM_STATUS_CALIBRATION_REQUIRED; } } this_adm.apr = NULL; cal_utils_clear_cal_block_q6maps(ADM_MAX_CAL_TYPES, this_adm.cal_data); mutex_lock(&this_adm.cal_data [ADM_CUSTOM_TOP_CAL]->lock); this_adm.set_custom_topology = 1; mutex_unlock(&this_adm.cal_data[ ADM_CUSTOM_TOP_CAL]->lock); rtac_clear_mapping(ADM_RTAC_CAL); /* * Free the ION memory and clear the map handles * for Source Tracking */ if (this_adm.sourceTrackingData.memmap.paddr != 0) { msm_audio_ion_free( this_adm.sourceTrackingData.dma_buf); this_adm.sourceTrackingData.dma_buf = NULL; this_adm.sourceTrackingData.memmap.size = 0; this_adm.sourceTrackingData.memmap.kvaddr = NULL; this_adm.sourceTrackingData.memmap.paddr = 0; this_adm.sourceTrackingData.apr_cmd_status = -1; atomic_set(&this_adm.mem_map_handles[ ADM_MEM_MAP_INDEX_SOURCE_TRACKING], 0); } } static int32_t adm_callback(struct apr_client_data *data, void *priv) { uint32_t *payload; int port_idx, copp_idx, idx, client_id; uint32_t num_modules; int ret; if (data == NULL) { pr_err("%s: data parameter is null\n", __func__); return -EINVAL; } payload = data->payload; if (data->opcode == RESET_EVENTS) { pr_debug("%s: Reset event is received: %d %d apr[%pK]\n", __func__, data->reset_event, data->reset_proc, this_adm.apr); if (this_adm.apr) adm_reset_data(); return 0; } adm_callback_debug_print(data); if (data->payload_size >= sizeof(uint32_t)) { copp_idx = (data->token) & 0XFF; port_idx = ((data->token) >> 16) & 0xFF; client_id = ((data->token) >> 8) & 0xFF; if (port_idx < 0 || port_idx >= AFE_MAX_PORTS) { pr_err("%s: Invalid port idx %d token %d\n", __func__, port_idx, data->token); return 0; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp idx %d token %d\n", __func__, copp_idx, data->token); return 0; } if (client_id < 0 || client_id >= ADM_CLIENT_ID_MAX) { pr_err("%s: Invalid client id %d\n", __func__, client_id); return 0; } if (data->opcode == APR_BASIC_RSP_RESULT) { pr_debug("%s: APR_BASIC_RSP_RESULT id 0x%x\n", __func__, payload[0]); if (!((client_id != ADM_CLIENT_ID_SOURCE_TRACKING) && ((payload[0] == ADM_CMD_SET_PP_PARAMS_V5) || (payload[0] == ADM_CMD_SET_PP_PARAMS_V6)))) { if (data->payload_size < (2 * sizeof(uint32_t))) { pr_err("%s: Invalid payload size %d\n", __func__, data->payload_size); return 0; } } if (payload[1] != 0) { pr_err("%s: cmd = 0x%x returned error = 0x%x\n", __func__, payload[0], payload[1]); } switch (payload[0]) { case ADM_CMD_SET_PP_PARAMS_V5: case ADM_CMD_SET_PP_PARAMS_V6: pr_debug("%s: ADM_CMD_SET_PP_PARAMS\n", __func__); if (client_id == ADM_CLIENT_ID_SOURCE_TRACKING) this_adm.sourceTrackingData. apr_cmd_status = payload[1]; else if (rtac_make_adm_callback(payload, data->payload_size)) break; /* * if soft volume is called and already * interrupted break out of the sequence here */ case ADM_CMD_DEVICE_OPEN_V5: case ADM_CMD_DEVICE_CLOSE_V5: case ADM_CMD_DEVICE_OPEN_V6: case ADM_CMD_DEVICE_OPEN_V8: pr_debug("%s: Basic callback received, wake up.\n", __func__); atomic_set(&this_adm.copp.stat[port_idx] [copp_idx], payload[1]); wake_up( &this_adm.copp.wait[port_idx][copp_idx]); break; case ADM_CMD_ADD_TOPOLOGIES: pr_debug("%s: callback received, ADM_CMD_ADD_TOPOLOGIES.\n", __func__); atomic_set(&this_adm.adm_stat, payload[1]); wake_up(&this_adm.adm_wait); break; case ADM_CMD_MATRIX_MAP_ROUTINGS_V5: case ADM_CMD_STREAM_DEVICE_MAP_ROUTINGS_V5: pr_debug("%s: Basic callback received, wake up.\n", __func__); atomic_set(&this_adm.matrix_map_stat, payload[1]); wake_up(&this_adm.matrix_map_wait); break; case ADM_CMD_SHARED_MEM_UNMAP_REGIONS: pr_debug("%s: ADM_CMD_SHARED_MEM_UNMAP_REGIONS\n", __func__); atomic_set(&this_adm.adm_stat, payload[1]); wake_up(&this_adm.adm_wait); break; case ADM_CMD_SHARED_MEM_MAP_REGIONS: pr_debug("%s: ADM_CMD_SHARED_MEM_MAP_REGIONS\n", __func__); /* Should only come here if there is an APR */ /* error or malformed APR packet. Otherwise */ /* response will be returned as */ if (payload[1] != 0) { pr_err("%s: ADM map error, resuming\n", __func__); atomic_set(&this_adm.adm_stat, payload[1]); wake_up(&this_adm.adm_wait); } break; case ADM_CMD_GET_PP_PARAMS_V5: case ADM_CMD_GET_PP_PARAMS_V6: pr_debug("%s: ADM_CMD_GET_PP_PARAMS\n", __func__); /* Should only come here if there is an APR */ /* error or malformed APR packet. Otherwise */ /* response will be returned as */ /* ADM_CMDRSP_GET_PP_PARAMS_V5 */ if (client_id == ADM_CLIENT_ID_SOURCE_TRACKING) { this_adm.sourceTrackingData. apr_cmd_status = payload[1]; if (payload[1] != 0) pr_err("%s: ADM get param error = %d\n", __func__, payload[1]); atomic_set(&this_adm.copp.stat [port_idx][copp_idx], payload[1]); wake_up(&this_adm.copp.wait [port_idx][copp_idx]); } else { if (payload[1] != 0) { pr_err("%s: ADM get param error = %d, resuming\n", __func__, payload[1]); rtac_make_adm_callback(payload, data->payload_size); } } break; case ADM_CMD_SET_PSPD_MTMX_STRTR_PARAMS_V5: case ADM_CMD_SET_PSPD_MTMX_STRTR_PARAMS_V6: pr_debug("%s:callback received PSPD MTMX, wake up\n", __func__); atomic_set(&this_adm.copp.stat[port_idx] [copp_idx], payload[1]); wake_up( &this_adm.copp.wait[port_idx][copp_idx]); break; case ADM_CMD_GET_PP_TOPO_MODULE_LIST: case ADM_CMD_GET_PP_TOPO_MODULE_LIST_V2: pr_debug("%s:ADM_CMD_GET_PP_TOPO_MODULE_LIST\n", __func__); if (payload[1] != 0) pr_err("%s: ADM get topo list error = %d\n", __func__, payload[1]); break; default: pr_err("%s: Unknown Cmd: 0x%x\n", __func__, payload[0]); break; } return 0; } switch (data->opcode) { case ADM_CMDRSP_DEVICE_OPEN_V5: case ADM_CMDRSP_DEVICE_OPEN_V6: case ADM_CMDRSP_DEVICE_OPEN_V8: { struct adm_cmd_rsp_device_open_v5 *open = NULL; if (data->payload_size < sizeof(struct adm_cmd_rsp_device_open_v5)) { pr_err("%s: Invalid payload size %d\n", __func__, data->payload_size); return 0; } open = (struct adm_cmd_rsp_device_open_v5 *)data->payload; if (open->copp_id == INVALID_COPP_ID) { pr_err("%s: invalid coppid rxed %d\n", __func__, open->copp_id); atomic_set(&this_adm.copp.stat[port_idx] [copp_idx], ADSP_EBADPARAM); wake_up( &this_adm.copp.wait[port_idx][copp_idx]); break; } atomic_set(&this_adm.copp.stat [port_idx][copp_idx], payload[0]); atomic_set(&this_adm.copp.id[port_idx][copp_idx], open->copp_id); pr_debug("%s: coppid rxed=%d\n", __func__, open->copp_id); wake_up(&this_adm.copp.wait[port_idx][copp_idx]); } break; case ADM_CMDRSP_GET_PP_PARAMS_V5: case ADM_CMDRSP_GET_PP_PARAMS_V6: pr_debug("%s: ADM_CMDRSP_GET_PP_PARAMS\n", __func__); if (client_id == ADM_CLIENT_ID_SOURCE_TRACKING) this_adm.sourceTrackingData.apr_cmd_status = payload[0]; else if (rtac_make_adm_callback(payload, data->payload_size)) break; idx = ADM_GET_PARAMETER_LENGTH * copp_idx; if (payload[0] == 0 && data->payload_size > 0) { ret = adm_process_get_param_response( data->opcode, idx, payload, data->payload_size); if (ret) pr_err("%s: Failed to process get param response, error %d\n", __func__, ret); } else { adm_get_parameters[idx] = -1; pr_err("%s: ADM_CMDRSP_GET_PP_PARAMS returned error 0x%x\n", __func__, payload[0]); } atomic_set(&this_adm.copp.stat[port_idx][copp_idx], payload[0]); wake_up(&this_adm.copp.wait[port_idx][copp_idx]); break; case ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST: case ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST_V2: pr_debug("%s: ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST\n", __func__); if (data->payload_size >= (2 * sizeof(uint32_t))) { num_modules = payload[1]; pr_debug("%s: Num modules %d\n", __func__, num_modules); if (payload[0]) { pr_err("%s: ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST, error = %d\n", __func__, payload[0]); } else if (num_modules > MAX_MODULES_IN_TOPO) { pr_err("%s: ADM_CMDRSP_GET_PP_TOPO_MODULE_LIST invalid num modules received, num modules = %d\n", __func__, num_modules); } else { ret = adm_process_get_topo_list_response( data->opcode, copp_idx, num_modules, payload, data->payload_size); if (ret) pr_err("%s: Failed to process get topo modules list response, error %d\n", __func__, ret); } } else { pr_err("%s: Invalid payload size %d\n", __func__, data->payload_size); } atomic_set(&this_adm.copp.stat[port_idx][copp_idx], payload[0]); wake_up(&this_adm.copp.wait[port_idx][copp_idx]); break; case ADM_CMDRSP_SHARED_MEM_MAP_REGIONS: pr_debug("%s: ADM_CMDRSP_SHARED_MEM_MAP_REGIONS\n", __func__); atomic_set(&this_adm.mem_map_handles[ atomic_read(&this_adm.mem_map_index)], *payload); atomic_set(&this_adm.adm_stat, 0); wake_up(&this_adm.adm_wait); break; default: pr_err("%s: Unknown cmd:0x%x\n", __func__, data->opcode); break; } } return 0; } static int adm_memory_map_regions(phys_addr_t *buf_add, uint32_t mempool_id, uint32_t *bufsz, uint32_t bufcnt) { struct avs_cmd_shared_mem_map_regions *mmap_regions = NULL; struct avs_shared_map_region_payload *mregions = NULL; void *mmap_region_cmd = NULL; void *payload = NULL; int ret = 0; int i = 0; int cmd_size = 0; pr_debug("%s:\n", __func__); if (this_adm.apr == NULL) { this_adm.apr = apr_register("ADSP", "ADM", adm_callback, 0xFFFFFFFF, &this_adm); if (this_adm.apr == NULL) { pr_err("%s: Unable to register ADM\n", __func__); ret = -ENODEV; return ret; } rtac_set_adm_handle(this_adm.apr); } cmd_size = sizeof(struct avs_cmd_shared_mem_map_regions) + sizeof(struct avs_shared_map_region_payload) * bufcnt; mmap_region_cmd = kzalloc(cmd_size, GFP_KERNEL); if (!mmap_region_cmd) return -ENOMEM; mmap_regions = (struct avs_cmd_shared_mem_map_regions *)mmap_region_cmd; mmap_regions->hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); mmap_regions->hdr.pkt_size = cmd_size; mmap_regions->hdr.src_port = 0; mmap_regions->hdr.dest_port = 0; mmap_regions->hdr.token = 0; mmap_regions->hdr.opcode = ADM_CMD_SHARED_MEM_MAP_REGIONS; mmap_regions->mem_pool_id = ADSP_MEMORY_MAP_SHMEM8_4K_POOL & 0x00ff; mmap_regions->num_regions = bufcnt & 0x00ff; mmap_regions->property_flag = 0x00; pr_debug("%s: map_regions->num_regions = %d\n", __func__, mmap_regions->num_regions); payload = ((u8 *) mmap_region_cmd + sizeof(struct avs_cmd_shared_mem_map_regions)); mregions = (struct avs_shared_map_region_payload *)payload; for (i = 0; i < bufcnt; i++) { mregions->shm_addr_lsw = lower_32_bits(buf_add[i]); mregions->shm_addr_msw = msm_audio_populate_upper_32_bits(buf_add[i]); mregions->mem_size_bytes = bufsz[i]; ++mregions; } atomic_set(&this_adm.adm_stat, -1); ret = apr_send_pkt(this_adm.apr, (uint32_t *) mmap_region_cmd); if (ret < 0) { pr_err("%s: mmap_regions op[0x%x]rc[%d]\n", __func__, mmap_regions->hdr.opcode, ret); ret = -EINVAL; goto fail_cmd; } ret = wait_event_timeout(this_adm.adm_wait, atomic_read(&this_adm.adm_stat) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: timeout. waited for memory_map\n", __func__); ret = -EINVAL; goto fail_cmd; } else if (atomic_read(&this_adm.adm_stat) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str( atomic_read(&this_adm.adm_stat))); ret = adsp_err_get_lnx_err_code( atomic_read(&this_adm.adm_stat)); goto fail_cmd; } fail_cmd: kfree(mmap_region_cmd); return ret; } static int adm_memory_unmap_regions(void) { struct avs_cmd_shared_mem_unmap_regions unmap_regions; int ret = 0; pr_debug("%s:\n", __func__); if (this_adm.apr == NULL) { pr_err("%s: APR handle NULL\n", __func__); return -EINVAL; } unmap_regions.hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); unmap_regions.hdr.pkt_size = sizeof(unmap_regions); unmap_regions.hdr.src_port = 0; unmap_regions.hdr.dest_port = 0; unmap_regions.hdr.token = 0; unmap_regions.hdr.opcode = ADM_CMD_SHARED_MEM_UNMAP_REGIONS; unmap_regions.mem_map_handle = atomic_read(&this_adm. mem_map_handles[atomic_read(&this_adm.mem_map_index)]); atomic_set(&this_adm.adm_stat, -1); ret = apr_send_pkt(this_adm.apr, (uint32_t *) &unmap_regions); if (ret < 0) { pr_err("%s: mmap_regions op[0x%x]rc[%d]\n", __func__, unmap_regions.hdr.opcode, ret); ret = -EINVAL; goto fail_cmd; } ret = wait_event_timeout(this_adm.adm_wait, atomic_read(&this_adm.adm_stat) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: timeout. waited for memory_unmap\n", __func__); ret = -EINVAL; goto fail_cmd; } else if (atomic_read(&this_adm.adm_stat) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str( atomic_read(&this_adm.adm_stat))); ret = adsp_err_get_lnx_err_code( atomic_read(&this_adm.adm_stat)); goto fail_cmd; } else { pr_debug("%s: Unmap handle 0x%x succeeded\n", __func__, unmap_regions.mem_map_handle); } fail_cmd: return ret; } static int remap_cal_data(struct cal_block_data *cal_block, int cal_index) { int ret = 0; if (cal_block->map_data.dma_buf == NULL) { pr_err("%s: No ION allocation for cal index %d!\n", __func__, cal_index); ret = -EINVAL; goto done; } if ((cal_block->map_data.map_size > 0) && (cal_block->map_data.q6map_handle == 0)) { atomic_set(&this_adm.mem_map_index, cal_index); ret = adm_memory_map_regions(&cal_block->cal_data.paddr, 0, (uint32_t *)&cal_block->map_data.map_size, 1); if (ret < 0) { pr_err("%s: ADM mmap did not work! size = %zd ret %d\n", __func__, cal_block->map_data.map_size, ret); pr_debug("%s: ADM mmap did not work! addr = 0x%pK, size = %zd ret %d\n", __func__, &cal_block->cal_data.paddr, cal_block->map_data.map_size, ret); goto done; } cal_block->map_data.q6map_handle = atomic_read(&this_adm. mem_map_handles[cal_index]); } done: return ret; } static void send_adm_custom_topology(void) { struct cal_block_data *cal_block = NULL; struct cmd_set_topologies adm_top; int cal_index = ADM_CUSTOM_TOP_CAL; int result; if (this_adm.cal_data[cal_index] == NULL) goto done; mutex_lock(&this_adm.cal_data[cal_index]->lock); if (!this_adm.set_custom_topology) goto unlock; this_adm.set_custom_topology = 0; cal_block = cal_utils_get_only_cal_block(this_adm.cal_data[cal_index]); if (cal_block == NULL || cal_utils_is_cal_stale(cal_block)) goto unlock; pr_debug("%s: Sending cal_index %d\n", __func__, cal_index); result = remap_cal_data(cal_block, cal_index); if (result) { pr_err("%s: Remap_cal_data failed for cal %d!\n", __func__, cal_index); goto unlock; } atomic_set(&this_adm.mem_map_index, cal_index); atomic_set(&this_adm.mem_map_handles[cal_index], cal_block->map_data.q6map_handle); if (cal_block->cal_data.size == 0) { pr_debug("%s: No ADM cal to send\n", __func__); goto unlock; } adm_top.hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(20), APR_PKT_VER); adm_top.hdr.pkt_size = sizeof(adm_top); adm_top.hdr.src_svc = APR_SVC_ADM; adm_top.hdr.src_domain = APR_DOMAIN_APPS; adm_top.hdr.src_port = 0; adm_top.hdr.dest_svc = APR_SVC_ADM; adm_top.hdr.dest_domain = APR_DOMAIN_ADSP; adm_top.hdr.dest_port = 0; adm_top.hdr.token = 0; adm_top.hdr.opcode = ADM_CMD_ADD_TOPOLOGIES; adm_top.payload_addr_lsw = lower_32_bits(cal_block->cal_data.paddr); adm_top.payload_addr_msw = msm_audio_populate_upper_32_bits( cal_block->cal_data.paddr); adm_top.mem_map_handle = cal_block->map_data.q6map_handle; adm_top.payload_size = cal_block->cal_data.size; atomic_set(&this_adm.adm_stat, -1); pr_debug("%s: Sending ADM_CMD_ADD_TOPOLOGIES payload = 0x%pK, size = %d\n", __func__, &cal_block->cal_data.paddr, adm_top.payload_size); result = apr_send_pkt(this_adm.apr, (uint32_t *)&adm_top); if (result < 0) { pr_err("%s: Set topologies failed payload size = %zd result %d\n", __func__, cal_block->cal_data.size, result); goto unlock; } /* Wait for the callback */ result = wait_event_timeout(this_adm.adm_wait, atomic_read(&this_adm.adm_stat) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!result) { pr_err("%s: Set topologies timed out payload size = %zd\n", __func__, cal_block->cal_data.size); goto unlock; } else if (atomic_read(&this_adm.adm_stat) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str( atomic_read(&this_adm.adm_stat))); result = adsp_err_get_lnx_err_code( atomic_read(&this_adm.adm_stat)); goto unlock; } unlock: mutex_unlock(&this_adm.cal_data[cal_index]->lock); done: return; } static int send_adm_cal_block(int port_id, int copp_idx, struct cal_block_data *cal_block, int perf_mode) { struct mem_mapping_hdr mem_hdr; int payload_size = 0; int port_idx = 0; int topology = 0; int result = 0; pr_debug("%s: Port id 0x%x,\n", __func__, port_id); if (!cal_block) { pr_debug("%s: No ADM cal to send for port_id = 0x%x!\n", __func__, port_id); result = -EINVAL; goto done; } if (cal_block->cal_data.size <= 0) { pr_debug("%s: No ADM cal sent for port_id = 0x%x!\n", __func__, port_id); result = -EINVAL; goto done; } memset(&mem_hdr, 0, sizeof(mem_hdr)); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0 || port_idx >= AFE_MAX_PORTS) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return -EINVAL; } else if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_idx 0x%x\n", __func__, copp_idx); return -EINVAL; } topology = atomic_read(&this_adm.copp.topology[port_idx][copp_idx]); if (perf_mode == LEGACY_PCM_MODE && topology == DS2_ADM_COPP_TOPOLOGY_ID) { pr_err("%s: perf_mode %d, topology 0x%x\n", __func__, perf_mode, topology); goto done; } mem_hdr.data_payload_addr_lsw = lower_32_bits(cal_block->cal_data.paddr); mem_hdr.data_payload_addr_msw = msm_audio_populate_upper_32_bits(cal_block->cal_data.paddr); mem_hdr.mem_map_handle = cal_block->map_data.q6map_handle; payload_size = cal_block->cal_data.size; adm_set_pp_params(port_id, copp_idx, &mem_hdr, NULL, payload_size); done: return result; } static struct cal_block_data *adm_find_cal_by_path(int cal_index, int path) { struct list_head *ptr, *next; struct cal_block_data *cal_block = NULL; struct audio_cal_info_audproc *audproc_cal_info = NULL; struct audio_cal_info_audvol *audvol_cal_info = NULL; pr_debug("%s:\n", __func__); list_for_each_safe(ptr, next, &this_adm.cal_data[cal_index]->cal_blocks) { cal_block = list_entry(ptr, struct cal_block_data, list); if (cal_utils_is_cal_stale(cal_block)) continue; if (cal_index == ADM_AUDPROC_CAL || cal_index == ADM_LSM_AUDPROC_CAL || cal_index == ADM_LSM_AUDPROC_PERSISTENT_CAL) { audproc_cal_info = cal_block->cal_info; if ((audproc_cal_info->path == path) && (cal_block->cal_data.size > 0)) return cal_block; } else if (cal_index == ADM_AUDVOL_CAL) { audvol_cal_info = cal_block->cal_info; if ((audvol_cal_info->path == path) && (cal_block->cal_data.size > 0)) return cal_block; } } pr_debug("%s: Can't find ADM cal for cal_index %d, path %d\n", __func__, cal_index, path); return NULL; } static struct cal_block_data *adm_find_cal_by_app_type(int cal_index, int path, int app_type) { struct list_head *ptr, *next; struct cal_block_data *cal_block = NULL; struct audio_cal_info_audproc *audproc_cal_info = NULL; struct audio_cal_info_audvol *audvol_cal_info = NULL; pr_debug("%s\n", __func__); list_for_each_safe(ptr, next, &this_adm.cal_data[cal_index]->cal_blocks) { cal_block = list_entry(ptr, struct cal_block_data, list); if (cal_utils_is_cal_stale(cal_block)) continue; if (cal_index == ADM_AUDPROC_CAL || cal_index == ADM_LSM_AUDPROC_CAL || cal_index == ADM_LSM_AUDPROC_PERSISTENT_CAL) { audproc_cal_info = cal_block->cal_info; if ((audproc_cal_info->path == path) && (audproc_cal_info->app_type == app_type) && (cal_block->cal_data.size > 0)) return cal_block; } else if (cal_index == ADM_AUDVOL_CAL) { audvol_cal_info = cal_block->cal_info; if ((audvol_cal_info->path == path) && (audvol_cal_info->app_type == app_type) && (cal_block->cal_data.size > 0)) return cal_block; } } pr_debug("%s: Can't find ADM cali for cal_index %d, path %d, app %d, defaulting to search by path\n", __func__, cal_index, path, app_type); return adm_find_cal_by_path(cal_index, path); } static struct cal_block_data *adm_find_cal(int cal_index, int path, int app_type, int acdb_id, int sample_rate) { struct list_head *ptr, *next; struct cal_block_data *cal_block = NULL; struct audio_cal_info_audproc *audproc_cal_info = NULL; struct audio_cal_info_audvol *audvol_cal_info = NULL; pr_debug("%s:\n", __func__); list_for_each_safe(ptr, next, &this_adm.cal_data[cal_index]->cal_blocks) { cal_block = list_entry(ptr, struct cal_block_data, list); if (cal_utils_is_cal_stale(cal_block)) continue; if (cal_index == ADM_AUDPROC_CAL || cal_index == ADM_LSM_AUDPROC_CAL || cal_index == ADM_LSM_AUDPROC_PERSISTENT_CAL) { audproc_cal_info = cal_block->cal_info; if ((audproc_cal_info->path == path) && (audproc_cal_info->app_type == app_type) && (audproc_cal_info->acdb_id == acdb_id) && (audproc_cal_info->sample_rate == sample_rate) && (cal_block->cal_data.size > 0)) return cal_block; } else if (cal_index == ADM_AUDVOL_CAL) { audvol_cal_info = cal_block->cal_info; if ((audvol_cal_info->path == path) && (audvol_cal_info->app_type == app_type) && (audvol_cal_info->acdb_id == acdb_id) && (cal_block->cal_data.size > 0)) return cal_block; } } pr_debug("%s: Can't find ADM cal for cal_index %d, path %d, app %d, acdb_id %d sample_rate %d defaulting to search by app type\n", __func__, cal_index, path, app_type, acdb_id, sample_rate); return adm_find_cal_by_app_type(cal_index, path, app_type); } static int adm_remap_and_send_cal_block(int cal_index, int port_id, int copp_idx, struct cal_block_data *cal_block, int perf_mode, int app_type, int acdb_id, int sample_rate) { int ret = 0; pr_debug("%s: Sending cal_index cal %d\n", __func__, cal_index); ret = remap_cal_data(cal_block, cal_index); if (ret) { pr_err("%s: Remap_cal_data failed for cal %d!\n", __func__, cal_index); goto done; } ret = send_adm_cal_block(port_id, copp_idx, cal_block, perf_mode); if (ret < 0) pr_debug("%s: No cal sent for cal_index %d, port_id = 0x%x! ret %d sample_rate %d\n", __func__, cal_index, port_id, ret, sample_rate); done: return ret; } static void send_adm_cal_type(int cal_index, int path, int port_id, int copp_idx, int perf_mode, int app_type, int acdb_id, int sample_rate) { struct cal_block_data *cal_block = NULL; int ret; pr_debug("%s: cal index %d\n", __func__, cal_index); if (this_adm.cal_data[cal_index] == NULL) { pr_debug("%s: cal_index %d not allocated!\n", __func__, cal_index); goto done; } mutex_lock(&this_adm.cal_data[cal_index]->lock); cal_block = adm_find_cal(cal_index, path, app_type, acdb_id, sample_rate); if (cal_block == NULL) goto unlock; ret = adm_remap_and_send_cal_block(cal_index, port_id, copp_idx, cal_block, perf_mode, app_type, acdb_id, sample_rate); cal_utils_mark_cal_used(cal_block); unlock: mutex_unlock(&this_adm.cal_data[cal_index]->lock); done: return; } static int get_cal_path(int path) { if (path == 0x1) return RX_DEVICE; else return TX_DEVICE; } static void send_adm_cal(int port_id, int copp_idx, int path, int perf_mode, int app_type, int acdb_id, int sample_rate, int passthr_mode) { pr_debug("%s: port id 0x%x copp_idx %d\n", __func__, port_id, copp_idx); if (passthr_mode != LISTEN) { send_adm_cal_type(ADM_AUDPROC_CAL, path, port_id, copp_idx, perf_mode, app_type, acdb_id, sample_rate); } else { send_adm_cal_type(ADM_LSM_AUDPROC_CAL, path, port_id, copp_idx, perf_mode, app_type, acdb_id, sample_rate); send_adm_cal_type(ADM_LSM_AUDPROC_PERSISTENT_CAL, path, port_id, copp_idx, perf_mode, app_type, acdb_id, sample_rate); } send_adm_cal_type(ADM_AUDVOL_CAL, path, port_id, copp_idx, perf_mode, app_type, acdb_id, sample_rate); } /** * adm_connect_afe_port - * command to send ADM connect AFE port * * @mode: value of mode for ADM connect AFE * @session_id: session active to connect * @port_id: Port ID number * * Returns 0 on success or error on failure */ int adm_connect_afe_port(int mode, int session_id, int port_id) { struct adm_cmd_connect_afe_port_v5 cmd; int ret = 0; int port_idx, copp_idx = 0; pr_debug("%s: port_id: 0x%x session id:%d mode:%d\n", __func__, port_id, session_id, mode); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return -EINVAL; } if (this_adm.apr == NULL) { this_adm.apr = apr_register("ADSP", "ADM", adm_callback, 0xFFFFFFFF, &this_adm); if (this_adm.apr == NULL) { pr_err("%s: Unable to register ADM\n", __func__); ret = -ENODEV; return ret; } rtac_set_adm_handle(this_adm.apr); } pr_debug("%s: Port ID 0x%x, index %d\n", __func__, port_id, port_idx); cmd.hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); cmd.hdr.pkt_size = sizeof(cmd); cmd.hdr.src_svc = APR_SVC_ADM; cmd.hdr.src_domain = APR_DOMAIN_APPS; cmd.hdr.src_port = port_id; cmd.hdr.dest_svc = APR_SVC_ADM; cmd.hdr.dest_domain = APR_DOMAIN_ADSP; cmd.hdr.dest_port = 0; /* Ignored */ cmd.hdr.token = port_idx << 16 | copp_idx; cmd.hdr.opcode = ADM_CMD_CONNECT_AFE_PORT_V5; cmd.mode = mode; cmd.session_id = session_id; cmd.afe_port_id = port_id; atomic_set(&this_adm.copp.stat[port_idx][copp_idx], -1); ret = apr_send_pkt(this_adm.apr, (uint32_t *)&cmd); if (ret < 0) { pr_err("%s: ADM enable for port_id: 0x%x failed ret %d\n", __func__, port_id, ret); ret = -EINVAL; goto fail_cmd; } /* Wait for the callback with copp id */ ret = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(&this_adm.copp.stat[port_idx][copp_idx]) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: ADM connect timedout for port_id: 0x%x\n", __func__, port_id); ret = -EINVAL; goto fail_cmd; } else if (atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str( atomic_read(&this_adm.copp.stat [port_idx][copp_idx]))); ret = adsp_err_get_lnx_err_code( atomic_read(&this_adm.copp.stat [port_idx][copp_idx])); goto fail_cmd; } atomic_inc(&this_adm.copp.cnt[port_idx][copp_idx]); return 0; fail_cmd: return ret; } EXPORT_SYMBOL(adm_connect_afe_port); int adm_arrange_mch_map(struct adm_cmd_device_open_v5 *open, int path, int channel_mode, int port_idx) { int rc = 0, idx; pr_debug("%s: channel mode %d", __func__, channel_mode); memset(open->dev_channel_mapping, 0, PCM_FORMAT_MAX_NUM_CHANNEL); switch (path) { case ADM_PATH_PLAYBACK: idx = ADM_MCH_MAP_IDX_PLAYBACK; break; case ADM_PATH_LIVE_REC: case ADM_PATH_NONLIVE_REC: idx = ADM_MCH_MAP_IDX_REC; break; default: goto non_mch_path; }; pr_info("%s : channel_mode = %d, num_channel = %d, set_channel_map = %d\n", __func__, channel_mode, open->dev_num_channel, multi_ch_maps[idx].set_channel_map); if ((open->dev_num_channel > 2) && (port_channel_map[port_idx].set_channel_map || multi_ch_maps[idx].set_channel_map)) { if (port_channel_map[port_idx].set_channel_map) memcpy(open->dev_channel_mapping, port_channel_map[port_idx].channel_mapping, PCM_FORMAT_MAX_NUM_CHANNEL); else memcpy(open->dev_channel_mapping, multi_ch_maps[idx].channel_mapping, PCM_FORMAT_MAX_NUM_CHANNEL); } else { if (channel_mode == 1) { open->dev_channel_mapping[0] = PCM_CHANNEL_FC; } else if (channel_mode == 2) { open->dev_channel_mapping[0] = PCM_CHANNEL_FL; open->dev_channel_mapping[1] = PCM_CHANNEL_FR; } else if (channel_mode == 3) { open->dev_channel_mapping[0] = PCM_CHANNEL_FL; open->dev_channel_mapping[1] = PCM_CHANNEL_FR; open->dev_channel_mapping[2] = PCM_CHANNEL_FC; } else if (channel_mode == 4) { open->dev_channel_mapping[0] = PCM_CHANNEL_FL; open->dev_channel_mapping[1] = PCM_CHANNEL_FR; open->dev_channel_mapping[2] = PCM_CHANNEL_LS; open->dev_channel_mapping[3] = PCM_CHANNEL_RS; } else if (channel_mode == 5) { open->dev_channel_mapping[0] = PCM_CHANNEL_FL; open->dev_channel_mapping[1] = PCM_CHANNEL_FR; open->dev_channel_mapping[2] = PCM_CHANNEL_FC; open->dev_channel_mapping[3] = PCM_CHANNEL_LS; open->dev_channel_mapping[4] = PCM_CHANNEL_RS; } else if (channel_mode == 6) { open->dev_channel_mapping[0] = PCM_CHANNEL_FL; open->dev_channel_mapping[1] = PCM_CHANNEL_FR; open->dev_channel_mapping[2] = PCM_CHANNEL_LFE; open->dev_channel_mapping[3] = PCM_CHANNEL_FC; open->dev_channel_mapping[4] = PCM_CHANNEL_LS; open->dev_channel_mapping[5] = PCM_CHANNEL_RS; } else if (channel_mode == 7) { open->dev_channel_mapping[0] = PCM_CHANNEL_FL; open->dev_channel_mapping[1] = PCM_CHANNEL_FR; open->dev_channel_mapping[2] = PCM_CHANNEL_FC; open->dev_channel_mapping[3] = PCM_CHANNEL_LFE; open->dev_channel_mapping[4] = PCM_CHANNEL_LB; open->dev_channel_mapping[5] = PCM_CHANNEL_RB; open->dev_channel_mapping[6] = PCM_CHANNEL_CS; } else if (channel_mode == 8) { open->dev_channel_mapping[0] = PCM_CHANNEL_FL; open->dev_channel_mapping[1] = PCM_CHANNEL_FR; open->dev_channel_mapping[2] = PCM_CHANNEL_LFE; open->dev_channel_mapping[3] = PCM_CHANNEL_FC; open->dev_channel_mapping[4] = PCM_CHANNEL_LS; open->dev_channel_mapping[5] = PCM_CHANNEL_RS; open->dev_channel_mapping[6] = PCM_CHANNEL_LB; open->dev_channel_mapping[7] = PCM_CHANNEL_RB; } else { pr_err("%s: invalid num_chan %d\n", __func__, channel_mode); rc = -EINVAL; goto inval_ch_mod; } } non_mch_path: inval_ch_mod: return rc; } int adm_arrange_mch_ep2_map(struct adm_cmd_device_open_v6 *open_v6, int channel_mode) { int rc = 0; memset(open_v6->dev_channel_mapping_eid2, 0, PCM_FORMAT_MAX_NUM_CHANNEL); if (channel_mode == 1) { open_v6->dev_channel_mapping_eid2[0] = PCM_CHANNEL_FC; } else if (channel_mode == 2) { open_v6->dev_channel_mapping_eid2[0] = PCM_CHANNEL_FL; open_v6->dev_channel_mapping_eid2[1] = PCM_CHANNEL_FR; } else if (channel_mode == 3) { open_v6->dev_channel_mapping_eid2[0] = PCM_CHANNEL_FL; open_v6->dev_channel_mapping_eid2[1] = PCM_CHANNEL_FR; open_v6->dev_channel_mapping_eid2[2] = PCM_CHANNEL_FC; } else if (channel_mode == 4) { open_v6->dev_channel_mapping_eid2[0] = PCM_CHANNEL_FL; open_v6->dev_channel_mapping_eid2[1] = PCM_CHANNEL_FR; open_v6->dev_channel_mapping_eid2[2] = PCM_CHANNEL_LS; open_v6->dev_channel_mapping_eid2[3] = PCM_CHANNEL_RS; } else if (channel_mode == 5) { open_v6->dev_channel_mapping_eid2[0] = PCM_CHANNEL_FL; open_v6->dev_channel_mapping_eid2[1] = PCM_CHANNEL_FR; open_v6->dev_channel_mapping_eid2[2] = PCM_CHANNEL_FC; open_v6->dev_channel_mapping_eid2[3] = PCM_CHANNEL_LS; open_v6->dev_channel_mapping_eid2[4] = PCM_CHANNEL_RS; } else if (channel_mode == 6) { open_v6->dev_channel_mapping_eid2[0] = PCM_CHANNEL_FL; open_v6->dev_channel_mapping_eid2[1] = PCM_CHANNEL_FR; open_v6->dev_channel_mapping_eid2[2] = PCM_CHANNEL_LFE; open_v6->dev_channel_mapping_eid2[3] = PCM_CHANNEL_FC; open_v6->dev_channel_mapping_eid2[4] = PCM_CHANNEL_LS; open_v6->dev_channel_mapping_eid2[5] = PCM_CHANNEL_RS; } else if (channel_mode == 8) { open_v6->dev_channel_mapping_eid2[0] = PCM_CHANNEL_FL; open_v6->dev_channel_mapping_eid2[1] = PCM_CHANNEL_FR; open_v6->dev_channel_mapping_eid2[2] = PCM_CHANNEL_LFE; open_v6->dev_channel_mapping_eid2[3] = PCM_CHANNEL_FC; open_v6->dev_channel_mapping_eid2[4] = PCM_CHANNEL_LS; open_v6->dev_channel_mapping_eid2[5] = PCM_CHANNEL_RS; open_v6->dev_channel_mapping_eid2[6] = PCM_CHANNEL_LB; open_v6->dev_channel_mapping_eid2[7] = PCM_CHANNEL_RB; } else { pr_err("%s: invalid num_chan %d\n", __func__, channel_mode); rc = -EINVAL; } return rc; } static int adm_arrange_mch_map_v8( struct adm_device_endpoint_payload *ep_payload, int path, int channel_mode, int port_idx) { int rc = 0, idx; memset(ep_payload->dev_channel_mapping, 0, PCM_FORMAT_MAX_NUM_CHANNEL_V8); switch (path) { case ADM_PATH_PLAYBACK: idx = ADM_MCH_MAP_IDX_PLAYBACK; break; case ADM_PATH_LIVE_REC: case ADM_PATH_NONLIVE_REC: idx = ADM_MCH_MAP_IDX_REC; break; default: goto non_mch_path; }; if ((ep_payload->dev_num_channel > 2) && (port_channel_map[port_idx].set_channel_map || multi_ch_maps[idx].set_channel_map)) { if (port_channel_map[port_idx].set_channel_map) memcpy(ep_payload->dev_channel_mapping, port_channel_map[port_idx].channel_mapping, PCM_FORMAT_MAX_NUM_CHANNEL_V8); else memcpy(ep_payload->dev_channel_mapping, multi_ch_maps[idx].channel_mapping, PCM_FORMAT_MAX_NUM_CHANNEL_V8); } else { if (channel_mode == 1) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FC; } else if (channel_mode == 2) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; } else if (channel_mode == 3) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_FC; } else if (channel_mode == 4) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_RS; } else if (channel_mode == 5) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_RS; } else if (channel_mode == 6) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RS; } else if (channel_mode == 7) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RB; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_CS; } else if (channel_mode == 8) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RB; } else if (channel_mode == 10) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RB; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[8] = PCM_CHANNEL_TFL; ep_payload->dev_channel_mapping[9] = PCM_CHANNEL_TFR; } else if (channel_mode == 12) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RB; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[8] = PCM_CHANNEL_TFL; ep_payload->dev_channel_mapping[9] = PCM_CHANNEL_TFR; ep_payload->dev_channel_mapping[10] = PCM_CHANNEL_TSL; ep_payload->dev_channel_mapping[11] = PCM_CHANNEL_TSR; } else if (channel_mode == 16) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RB; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[8] = PCM_CHANNEL_TFL; ep_payload->dev_channel_mapping[9] = PCM_CHANNEL_TFR; ep_payload->dev_channel_mapping[10] = PCM_CHANNEL_TSL; ep_payload->dev_channel_mapping[11] = PCM_CHANNEL_TSR; ep_payload->dev_channel_mapping[12] = PCM_CHANNEL_FLC; ep_payload->dev_channel_mapping[13] = PCM_CHANNEL_FRC; ep_payload->dev_channel_mapping[14] = PCM_CHANNEL_RLC; ep_payload->dev_channel_mapping[15] = PCM_CHANNEL_RRC; } else { pr_err("%s: invalid num_chan %d\n", __func__, channel_mode); rc = -EINVAL; goto inval_ch_mod; } } non_mch_path: inval_ch_mod: return rc; } static int adm_arrange_mch_ep2_map_v8( struct adm_device_endpoint_payload *ep_payload, int channel_mode) { int rc = 0; memset(ep_payload->dev_channel_mapping, 0, PCM_FORMAT_MAX_NUM_CHANNEL_V8); if (channel_mode == 1) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FC; } else if (channel_mode == 2) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; } else if (channel_mode == 3) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_FC; } else if (channel_mode == 4) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_RS; } else if (channel_mode == 5) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_RS; } else if (channel_mode == 6) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RS; } else if (channel_mode == 8) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RB; } else if (channel_mode == 10) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RB; ep_payload->dev_channel_mapping[8] = PCM_CHANNEL_CS; ep_payload->dev_channel_mapping[9] = PCM_CHANNELS; } else if (channel_mode == 12) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RB; ep_payload->dev_channel_mapping[8] = PCM_CHANNEL_TFL; ep_payload->dev_channel_mapping[9] = PCM_CHANNEL_TFR; ep_payload->dev_channel_mapping[10] = PCM_CHANNEL_TSL; ep_payload->dev_channel_mapping[11] = PCM_CHANNEL_TSR; } else if (channel_mode == 16) { ep_payload->dev_channel_mapping[0] = PCM_CHANNEL_FL; ep_payload->dev_channel_mapping[1] = PCM_CHANNEL_FR; ep_payload->dev_channel_mapping[2] = PCM_CHANNEL_LFE; ep_payload->dev_channel_mapping[3] = PCM_CHANNEL_FC; ep_payload->dev_channel_mapping[4] = PCM_CHANNEL_LS; ep_payload->dev_channel_mapping[5] = PCM_CHANNEL_RS; ep_payload->dev_channel_mapping[6] = PCM_CHANNEL_LB; ep_payload->dev_channel_mapping[7] = PCM_CHANNEL_RB; ep_payload->dev_channel_mapping[8] = PCM_CHANNEL_CS; ep_payload->dev_channel_mapping[9] = PCM_CHANNELS; ep_payload->dev_channel_mapping[10] = PCM_CHANNEL_CVH; ep_payload->dev_channel_mapping[11] = PCM_CHANNEL_MS; ep_payload->dev_channel_mapping[12] = PCM_CHANNEL_FLC; ep_payload->dev_channel_mapping[13] = PCM_CHANNEL_FRC; ep_payload->dev_channel_mapping[14] = PCM_CHANNEL_RLC; ep_payload->dev_channel_mapping[15] = PCM_CHANNEL_RRC; } else { pr_err("%s: invalid num_chan %d\n", __func__, channel_mode); rc = -EINVAL; } return rc; } /** * adm_open - * command to send ADM open * * @port_id: port id number * @path: direction or ADM path type * @rate: sample rate of session * @channel_mode: number of channels set * @topology: topology active for this session * @perf_mode: performance mode like LL/ULL/.. * @bit_width: bit width to set for copp * @app_type: App type used for this session * @acdb_id: ACDB ID of this device * * Returns 0 on success or error on failure */ int adm_open(int port_id, int path, int rate, int channel_mode, int topology, int perf_mode, uint16_t bit_width, int app_type, int acdb_id) { struct adm_cmd_device_open_v5 open; struct adm_cmd_device_open_v6 open_v6; struct adm_cmd_device_open_v8 open_v8; struct adm_device_endpoint_payload ep1_payload; struct adm_device_endpoint_payload ep2_payload; int ep1_payload_size = 0; int ep2_payload_size = 0; int ret = 0; int port_idx, flags; int copp_idx = -1; int tmp_port = q6audio_get_port_id(port_id); void *adm_params = NULL; int param_size; pr_info("%s:port %#x path:%d rate:%d mode:%d perf_mode:%d,topo_id %d\n", __func__, port_id, path, rate, channel_mode, perf_mode, topology); pr_info("%s:bit_width:%d app_type:%#x acdb_id:%d\n", __func__, bit_width, app_type, acdb_id); port_id = q6audio_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return -EINVAL; } if (channel_mode < 0 || channel_mode > 32) { pr_err("%s: Invalid channel number 0x%x\n", __func__, channel_mode); return -EINVAL; } if (this_adm.apr == NULL) { this_adm.apr = apr_register("ADSP", "ADM", adm_callback, 0xFFFFFFFF, &this_adm); if (this_adm.apr == NULL) { pr_err("%s: Unable to register ADM\n", __func__); return -ENODEV; } rtac_set_adm_handle(this_adm.apr); } if (perf_mode == ULL_POST_PROCESSING_PCM_MODE) { flags = ADM_ULL_POST_PROCESSING_DEVICE_SESSION; if ((topology == DOLBY_ADM_COPP_TOPOLOGY_ID) || (topology == DS2_ADM_COPP_TOPOLOGY_ID) || (topology == SRS_TRUMEDIA_TOPOLOGY_ID)) topology = DEFAULT_COPP_TOPOLOGY; } else if (perf_mode == ULTRA_LOW_LATENCY_PCM_MODE) { flags = ADM_ULTRA_LOW_LATENCY_DEVICE_SESSION; topology = NULL_COPP_TOPOLOGY; rate = ULL_SUPPORTED_SAMPLE_RATE; bit_width = ULL_SUPPORTED_BITS_PER_SAMPLE; } else if (perf_mode == LOW_LATENCY_PCM_MODE) { flags = ADM_LOW_LATENCY_DEVICE_SESSION; if ((topology == DOLBY_ADM_COPP_TOPOLOGY_ID) || (topology == DS2_ADM_COPP_TOPOLOGY_ID) || (topology == SRS_TRUMEDIA_TOPOLOGY_ID)) topology = DEFAULT_COPP_TOPOLOGY; } else { if ((path == ADM_PATH_COMPRESSED_RX) || (path == ADM_PATH_COMPRESSED_TX)) flags = 0; else flags = ADM_LEGACY_DEVICE_SESSION; } if ((topology == VPM_TX_SM_ECNS_V2_COPP_TOPOLOGY) || (topology == VPM_TX_DM_FLUENCE_EF_COPP_TOPOLOGY)) { if ((rate != ADM_CMD_COPP_OPEN_SAMPLE_RATE_8K) && (rate != ADM_CMD_COPP_OPEN_SAMPLE_RATE_16K) && (rate != ADM_CMD_COPP_OPEN_SAMPLE_RATE_32K) && (rate != ADM_CMD_COPP_OPEN_SAMPLE_RATE_48K)) rate = 16000; } if ((topology == VPM_TX_DM_FLUENCE_COPP_TOPOLOGY) || (topology == VPM_TX_DM_RFECNS_COPP_TOPOLOGY)) { if ((rate != ADM_CMD_COPP_OPEN_SAMPLE_RATE_8K) && (rate != ADM_CMD_COPP_OPEN_SAMPLE_RATE_16K) && (rate != ADM_CMD_COPP_OPEN_SAMPLE_RATE_32K)) rate = 16000; } if (topology == FFECNS_TOPOLOGY) { this_adm.ffecns_port_id = port_id; pr_debug("%s: ffecns port id =%x\n", __func__, this_adm.ffecns_port_id); } if ((topology == VPM_TX_SM_LVVEFQ_COPP_TOPOLOGY) || (topology == VPM_TX_DM_LVVEFQ_COPP_TOPOLOGY) || (topology == VPM_TX_SM_LVSAFQ_COPP_TOPOLOGY) || (topology == VPM_TX_DM_LVSAFQ_COPP_TOPOLOGY) || (topology == VOICE_TX_DIAMONDVOICE_FVSAM_SM) || (topology == VOICE_TX_DIAMONDVOICE_FRSAM_DM) || (topology == VOICE_TX_DIAMONDVOICE_FVSAM_DM) || (topology == VOICE_TX_DIAMONDVOICE_FVSAM_QM)) rate = 16000; if (topology == VPM_TX_VOICE_SMECNS_V2_COPP_TOPOLOGY) channel_mode = 1; /* * Routing driver reuses the same adm for streams with the same * app_type, sample_rate etc. * This isn't allowed for ULL streams as per the DSP interface */ if (perf_mode != ULTRA_LOW_LATENCY_PCM_MODE) copp_idx = adm_get_idx_if_copp_exists(port_idx, topology, perf_mode, rate, bit_width, app_type); if (copp_idx < 0) { copp_idx = adm_get_next_available_copp(port_idx); if (copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: exceeded copp id %d\n", __func__, copp_idx); return -EINVAL; } atomic_set(&this_adm.copp.cnt[port_idx][copp_idx], 0); atomic_set(&this_adm.copp.topology[port_idx][copp_idx], topology); atomic_set(&this_adm.copp.mode[port_idx][copp_idx], perf_mode); atomic_set(&this_adm.copp.rate[port_idx][copp_idx], rate); atomic_set(&this_adm.copp.channels[port_idx][copp_idx], channel_mode); atomic_set(&this_adm.copp.bit_width[port_idx][copp_idx], bit_width); atomic_set(&this_adm.copp.app_type[port_idx][copp_idx], app_type); atomic_set(&this_adm.copp.acdb_id[port_idx][copp_idx], acdb_id); set_bit(ADM_STATUS_CALIBRATION_REQUIRED, (void *)&this_adm.copp.adm_status[port_idx][copp_idx]); if ((path != ADM_PATH_COMPRESSED_RX) && (path != ADM_PATH_COMPRESSED_TX)) send_adm_custom_topology(); } if (this_adm.copp.adm_delay[port_idx][copp_idx] && perf_mode == LEGACY_PCM_MODE) { atomic_set(&this_adm.copp.adm_delay_stat[port_idx][copp_idx], 1); this_adm.copp.adm_delay[port_idx][copp_idx] = 0; wake_up(&this_adm.copp.adm_delay_wait[port_idx][copp_idx]); } /* Create a COPP if port id are not enabled */ if (atomic_read(&this_adm.copp.cnt[port_idx][copp_idx]) == 0) { pr_debug("%s: open ADM: port_idx: %d, copp_idx: %d\n", __func__, port_idx, copp_idx); if ((topology == SRS_TRUMEDIA_TOPOLOGY_ID) && perf_mode == LEGACY_PCM_MODE) { int res; atomic_set(&this_adm.mem_map_index, ADM_SRS_TRUMEDIA); msm_dts_srs_tm_ion_memmap(&this_adm.outband_memmap); res = adm_memory_map_regions( &this_adm.outband_memmap.paddr, 0, (uint32_t *)&this_adm.outband_memmap.size, 1); if (res < 0) { pr_err("%s: SRS adm_memory_map_regions failed! addr = 0x%pK, size = %d\n", __func__, (void *)this_adm.outband_memmap.paddr, (uint32_t)this_adm.outband_memmap.size); } } if ((q6core_get_avcs_api_version_per_service( APRV2_IDS_SERVICE_ID_ADSP_ADM_V) >= ADSP_ADM_API_VERSION_V3) && q6core_use_Q6_32ch_support()) { memset(&open_v8, 0, sizeof(open_v8)); memset(&ep1_payload, 0, sizeof(ep1_payload)); memset(&ep2_payload, 0, sizeof(ep2_payload)); open_v8.hdr.hdr_field = APR_HDR_FIELD( APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); open_v8.hdr.src_svc = APR_SVC_ADM; open_v8.hdr.src_domain = APR_DOMAIN_APPS; open_v8.hdr.src_port = tmp_port; open_v8.hdr.dest_svc = APR_SVC_ADM; open_v8.hdr.dest_domain = APR_DOMAIN_ADSP; open_v8.hdr.dest_port = tmp_port; open_v8.hdr.token = port_idx << 16 | copp_idx; open_v8.hdr.opcode = ADM_CMD_DEVICE_OPEN_V8; if (this_adm.native_mode != 0) { open_v8.flags = flags | (this_adm.native_mode << 11); this_adm.native_mode = 0; } else { open_v8.flags = flags; } open_v8.mode_of_operation = path; open_v8.endpoint_id_1 = tmp_port; open_v8.endpoint_id_2 = 0xFFFF; open_v8.endpoint_id_3 = 0xFFFF; open_v8.topology_id = topology; open_v8.reserved = 0; /* variable endpoint payload */ ep1_payload.dev_num_channel = channel_mode & 0x00FF; ep1_payload.bit_width = bit_width; ep1_payload.sample_rate = rate; ret = adm_arrange_mch_map_v8(&ep1_payload, path, channel_mode, port_idx); if (ret) return ret; pr_debug("%s: port_id=0x%x %x %x topology_id=0x%X flags %x ref_ch %x\n", __func__, open_v8.endpoint_id_1, open_v8.endpoint_id_2, open_v8.endpoint_id_3, open_v8.topology_id, open_v8.flags, this_adm.num_ec_ref_rx_chans); ep1_payload_size = 8 + roundup(ep1_payload.dev_num_channel, 4); param_size = sizeof(struct adm_cmd_device_open_v8) + ep1_payload_size; atomic_set(&this_adm.copp.stat[port_idx][copp_idx], -1); if ((this_adm.num_ec_ref_rx_chans != 0) && (path != ADM_PATH_PLAYBACK) && (open_v8.endpoint_id_2 != 0xFFFF)) { open_v8.endpoint_id_2 = this_adm.ec_ref_rx; this_adm.ec_ref_rx = -1; ep2_payload.dev_num_channel = this_adm.num_ec_ref_rx_chans; this_adm.num_ec_ref_rx_chans = 0; if (this_adm.ec_ref_rx_bit_width != 0) { ep2_payload.bit_width = this_adm.ec_ref_rx_bit_width; } else { ep2_payload.bit_width = bit_width; } if (this_adm.ec_ref_rx_sampling_rate != 0) { ep2_payload.sample_rate = this_adm.ec_ref_rx_sampling_rate; } else { ep2_payload.sample_rate = rate; } pr_debug("%s: adm open_v8 eid2_channels=%d eid2_bit_width=%d eid2_rate=%d\n", __func__, ep2_payload.dev_num_channel, ep2_payload.bit_width, ep2_payload.sample_rate); ret = adm_arrange_mch_ep2_map_v8(&ep2_payload, ep2_payload.dev_num_channel); if (ret) return ret; ep2_payload_size = 8 + roundup(ep2_payload.dev_num_channel, 4); param_size += ep2_payload_size; } open_v8.hdr.pkt_size = param_size; adm_params = kzalloc(param_size, GFP_KERNEL); if (!adm_params) return -ENOMEM; memcpy(adm_params, &open_v8, sizeof(open_v8)); memcpy(adm_params + sizeof(open_v8), (void *)&ep1_payload, ep1_payload_size); if ((this_adm.num_ec_ref_rx_chans != 0) && (path != ADM_PATH_PLAYBACK) && (open_v8.endpoint_id_2 != 0xFFFF)) { memcpy(adm_params + sizeof(open_v8) + ep1_payload_size, (void *)&ep2_payload, ep2_payload_size); } ret = apr_send_pkt(this_adm.apr, (uint32_t *)adm_params); if (ret < 0) { pr_err("%s: port_id: 0x%x for[0x%x] failed %d for open_v8\n", __func__, tmp_port, port_id, ret); return -EINVAL; } kfree(adm_params); } else { open.hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); open.hdr.pkt_size = sizeof(open); open.hdr.src_svc = APR_SVC_ADM; open.hdr.src_domain = APR_DOMAIN_APPS; open.hdr.src_port = tmp_port; open.hdr.dest_svc = APR_SVC_ADM; open.hdr.dest_domain = APR_DOMAIN_ADSP; open.hdr.dest_port = tmp_port; open.hdr.token = port_idx << 16 | copp_idx; open.hdr.opcode = ADM_CMD_DEVICE_OPEN_V5; open.flags = flags; open.mode_of_operation = path; open.endpoint_id_1 = tmp_port; open.endpoint_id_2 = 0xFFFF; if (this_adm.ec_ref_rx && (path != 1)) { open.endpoint_id_2 = this_adm.ec_ref_rx; } open.topology_id = topology; open.dev_num_channel = channel_mode & 0x00FF; open.bit_width = bit_width; WARN_ON((perf_mode == ULTRA_LOW_LATENCY_PCM_MODE) && (rate != ULL_SUPPORTED_SAMPLE_RATE)); open.sample_rate = rate; ret = adm_arrange_mch_map(&open, path, channel_mode, port_idx); if (ret) return ret; pr_debug("%s: port_id=0x%x rate=%d topology_id=0x%X\n", __func__, open.endpoint_id_1, open.sample_rate, open.topology_id); atomic_set(&this_adm.copp.stat[port_idx][copp_idx], -1); if ((this_adm.num_ec_ref_rx_chans != 0) && (path != 1) && (open.endpoint_id_2 != 0xFFFF)) { memset(&open_v6, 0, sizeof(struct adm_cmd_device_open_v6)); memcpy(&open_v6, &open, sizeof(struct adm_cmd_device_open_v5)); open_v6.hdr.opcode = ADM_CMD_DEVICE_OPEN_V6; open_v6.hdr.pkt_size = sizeof(open_v6); open_v6.dev_num_channel_eid2 = this_adm.num_ec_ref_rx_chans; if (this_adm.ec_ref_rx_bit_width != 0) { open_v6.bit_width_eid2 = this_adm.ec_ref_rx_bit_width; } else { open_v6.bit_width_eid2 = bit_width; } if (this_adm.ec_ref_rx_sampling_rate != 0) { open_v6.sample_rate_eid2 = this_adm.ec_ref_rx_sampling_rate; } else { open_v6.sample_rate_eid2 = rate; } pr_debug("%s: eid2_channels=%d eid2_bit_width=%d eid2_rate=%d\n", __func__, open_v6.dev_num_channel_eid2, open_v6.bit_width_eid2, open_v6.sample_rate_eid2); ret = adm_arrange_mch_ep2_map(&open_v6, open_v6.dev_num_channel_eid2); if (ret) return ret; ret = apr_send_pkt(this_adm.apr, (uint32_t *)&open_v6); } else { ret = apr_send_pkt(this_adm.apr, (uint32_t *)&open); } if (ret < 0) { pr_err("%s: port_id: 0x%x for[0x%x] failed %d\n", __func__, tmp_port, port_id, ret); return -EINVAL; } } /* Wait for the callback with copp id */ ret = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: ADM open timedout for port_id: 0x%x for [0x%x]\n", __func__, tmp_port, port_id); return -EINVAL; } else if (atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str( atomic_read(&this_adm.copp.stat [port_idx][copp_idx]))); return adsp_err_get_lnx_err_code( atomic_read(&this_adm.copp.stat [port_idx][copp_idx])); } } atomic_inc(&this_adm.copp.cnt[port_idx][copp_idx]); return copp_idx; } EXPORT_SYMBOL(adm_open); /** * adm_copp_mfc_cfg - * command to send ADM MFC config * * @port_id: Port ID number * @copp_idx: copp index assigned * @dst_sample_rate: sink sample rate * */ void adm_copp_mfc_cfg(int port_id, int copp_idx, int dst_sample_rate) { struct audproc_mfc_param_media_fmt mfc_cfg; struct adm_cmd_device_open_v5 open; struct param_hdr_v3 param_hdr; int port_idx; int rc = 0; int i = 0; port_id = q6audio_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id %#x\n", __func__, port_id); goto fail_cmd; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_num: %d\n", __func__, copp_idx); goto fail_cmd; } memset(&mfc_cfg, 0, sizeof(mfc_cfg)); memset(&open, 0, sizeof(open)); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = AUDPROC_MODULE_ID_MFC; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = AUDPROC_PARAM_ID_MFC_OUTPUT_MEDIA_FORMAT; param_hdr.param_size = sizeof(mfc_cfg); mfc_cfg.sampling_rate = dst_sample_rate; mfc_cfg.bits_per_sample = atomic_read(&this_adm.copp.bit_width[port_idx][copp_idx]); open.dev_num_channel = mfc_cfg.num_channels = atomic_read(&this_adm.copp.channels[port_idx][copp_idx]); rc = adm_arrange_mch_map(&open, ADM_PATH_PLAYBACK, mfc_cfg.num_channels, port_idx); if (rc < 0) { pr_err("%s: unable to get channal map\n", __func__); goto fail_cmd; } for (i = 0; i < mfc_cfg.num_channels; i++) mfc_cfg.channel_type[i] = (uint16_t) open.dev_channel_mapping[i]; atomic_set(&this_adm.copp.stat[port_idx][copp_idx], -1); pr_debug("%s: mfc config: port_idx %d copp_idx %d copp SR %d copp BW %d copp chan %d o/p SR %d\n", __func__, port_idx, copp_idx, atomic_read(&this_adm.copp.rate[port_idx][copp_idx]), mfc_cfg.bits_per_sample, mfc_cfg.num_channels, mfc_cfg.sampling_rate); rc = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &mfc_cfg); if (rc) pr_err("%s: Failed to set media format configuration data, err %d\n", __func__, rc); fail_cmd: return; } EXPORT_SYMBOL(adm_copp_mfc_cfg); static void route_set_opcode_matrix_id( struct adm_cmd_matrix_map_routings_v5 **route_addr, int path, uint32_t passthr_mode) { struct adm_cmd_matrix_map_routings_v5 *route = *route_addr; switch (path) { case ADM_PATH_PLAYBACK: route->hdr.opcode = ADM_CMD_MATRIX_MAP_ROUTINGS_V5; route->matrix_id = ADM_MATRIX_ID_AUDIO_RX; break; case ADM_PATH_LIVE_REC: if (passthr_mode == LISTEN) { route->hdr.opcode = ADM_CMD_STREAM_DEVICE_MAP_ROUTINGS_V5; route->matrix_id = ADM_MATRIX_ID_LISTEN_TX; break; } /* fall through to set matrix id for non-listen case */ case ADM_PATH_NONLIVE_REC: route->hdr.opcode = ADM_CMD_MATRIX_MAP_ROUTINGS_V5; route->matrix_id = ADM_MATRIX_ID_AUDIO_TX; break; case ADM_PATH_COMPRESSED_RX: route->hdr.opcode = ADM_CMD_STREAM_DEVICE_MAP_ROUTINGS_V5; route->matrix_id = ADM_MATRIX_ID_COMPRESSED_AUDIO_RX; break; case ADM_PATH_COMPRESSED_TX: route->hdr.opcode = ADM_CMD_STREAM_DEVICE_MAP_ROUTINGS_V5; route->matrix_id = ADM_MATRIX_ID_COMPRESSED_AUDIO_TX; break; default: pr_err("%s: Wrong path set[%d]\n", __func__, path); break; } pr_debug("%s: opcode 0x%x, matrix id %d\n", __func__, route->hdr.opcode, route->matrix_id); } /** * adm_matrix_map - * command to send ADM matrix map for ADM copp list * * @path: direction or ADM path type * @payload_map: have info of session id and associated copp_idx/num_copps * @perf_mode: performance mode like LL/ULL/.. * @passthr_mode: flag to indicate passthrough mode * * Returns 0 on success or error on failure */ int adm_matrix_map(int path, struct route_payload payload_map, int perf_mode, uint32_t passthr_mode) { struct adm_cmd_matrix_map_routings_v5 *route; struct adm_session_map_node_v5 *node; uint16_t *copps_list; int cmd_size = 0; int ret = 0, i = 0; void *payload = NULL; void *matrix_map = NULL; int port_idx, copp_idx; /* Assumes port_ids have already been validated during adm_open */ cmd_size = (sizeof(struct adm_cmd_matrix_map_routings_v5) + sizeof(struct adm_session_map_node_v5) + (sizeof(uint32_t) * payload_map.num_copps)); matrix_map = kzalloc(cmd_size, GFP_KERNEL); if (matrix_map == NULL) { pr_err("%s: Mem alloc failed\n", __func__); ret = -EINVAL; return ret; } route = (struct adm_cmd_matrix_map_routings_v5 *)matrix_map; route->hdr.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); route->hdr.pkt_size = cmd_size; route->hdr.src_svc = 0; route->hdr.src_domain = APR_DOMAIN_APPS; route->hdr.src_port = 0; /* Ignored */; route->hdr.dest_svc = APR_SVC_ADM; route->hdr.dest_domain = APR_DOMAIN_ADSP; route->hdr.dest_port = 0; /* Ignored */; route->hdr.token = 0; route->num_sessions = 1; route_set_opcode_matrix_id(&route, path, passthr_mode); payload = ((u8 *)matrix_map + sizeof(struct adm_cmd_matrix_map_routings_v5)); node = (struct adm_session_map_node_v5 *)payload; node->session_id = payload_map.session_id; node->num_copps = payload_map.num_copps; payload = (u8 *)node + sizeof(struct adm_session_map_node_v5); copps_list = (uint16_t *)payload; for (i = 0; i < payload_map.num_copps; i++) { port_idx = adm_validate_and_get_port_index(payload_map.port_id[i]); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, payload_map.port_id[i]); ret = -EINVAL; goto fail_cmd; } copp_idx = payload_map.copp_idx[i]; copps_list[i] = atomic_read(&this_adm.copp.id[port_idx] [copp_idx]); } atomic_set(&this_adm.matrix_map_stat, -1); ret = apr_send_pkt(this_adm.apr, (uint32_t *)matrix_map); if (ret < 0) { pr_err("%s: routing for syream %d failed ret %d\n", __func__, payload_map.session_id, ret); ret = -EINVAL; goto fail_cmd; } ret = wait_event_timeout(this_adm.matrix_map_wait, atomic_read(&this_adm.matrix_map_stat) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: routing for syream %d failed\n", __func__, payload_map.session_id); ret = -EINVAL; goto fail_cmd; } else if (atomic_read(&this_adm.matrix_map_stat) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str(atomic_read( &this_adm.matrix_map_stat))); ret = adsp_err_get_lnx_err_code( atomic_read(&this_adm.matrix_map_stat)); goto fail_cmd; } if ((perf_mode != ULTRA_LOW_LATENCY_PCM_MODE) && (path != ADM_PATH_COMPRESSED_RX)) { for (i = 0; i < payload_map.num_copps; i++) { port_idx = afe_get_port_index(payload_map.port_id[i]); copp_idx = payload_map.copp_idx[i]; if (port_idx < 0 || copp_idx < 0 || (copp_idx > MAX_COPPS_PER_PORT - 1)) { pr_err("%s: Invalid idx port_idx %d copp_idx %d\n", __func__, port_idx, copp_idx); continue; } rtac_add_adm_device(payload_map.port_id[i], atomic_read(&this_adm.copp.id [port_idx][copp_idx]), get_cal_path(path), payload_map.session_id, payload_map.app_type[i], payload_map.acdb_dev_id[i]); if (!test_bit(ADM_STATUS_CALIBRATION_REQUIRED, (void *)&this_adm.copp.adm_status[port_idx] [copp_idx])) { pr_debug("%s: adm copp[0x%x][%d] already sent", __func__, port_idx, copp_idx); continue; } send_adm_cal(payload_map.port_id[i], copp_idx, get_cal_path(path), perf_mode, payload_map.app_type[i], payload_map.acdb_dev_id[i], payload_map.sample_rate[i], passthr_mode); /* ADM COPP calibration is already sent */ clear_bit(ADM_STATUS_CALIBRATION_REQUIRED, (void *)&this_adm.copp. adm_status[port_idx][copp_idx]); pr_debug("%s: copp_id: %d\n", __func__, atomic_read(&this_adm.copp.id[port_idx] [copp_idx])); } } fail_cmd: kfree(matrix_map); return ret; } EXPORT_SYMBOL(adm_matrix_map); /** * adm_ec_ref_rx_id - * Update EC ref port ID * */ void adm_ec_ref_rx_id(int port_id) { this_adm.ec_ref_rx = port_id; pr_debug("%s: ec_ref_rx:%d\n", __func__, this_adm.ec_ref_rx); } EXPORT_SYMBOL(adm_ec_ref_rx_id); /** * adm_num_ec_ref_rx_chans - * Update EC ref number of channels * */ void adm_num_ec_ref_rx_chans(int num_chans) { this_adm.num_ec_ref_rx_chans = num_chans; pr_debug("%s: num_ec_ref_rx_chans:%d\n", __func__, this_adm.num_ec_ref_rx_chans); } EXPORT_SYMBOL(adm_num_ec_ref_rx_chans); /** * adm_ec_ref_rx_bit_width - * Update EC ref bit_width * */ void adm_ec_ref_rx_bit_width(int bit_width) { this_adm.ec_ref_rx_bit_width = bit_width; pr_debug("%s: ec_ref_rx_bit_width:%d\n", __func__, this_adm.ec_ref_rx_bit_width); } EXPORT_SYMBOL(adm_ec_ref_rx_bit_width); /** * adm_ec_ref_rx_sampling_rate - * Update EC ref sample rate * */ void adm_ec_ref_rx_sampling_rate(int sampling_rate) { this_adm.ec_ref_rx_sampling_rate = sampling_rate; pr_debug("%s: ec_ref_rx_sampling_rate:%d\n", __func__, this_adm.ec_ref_rx_sampling_rate); } EXPORT_SYMBOL(adm_ec_ref_rx_sampling_rate); /** * adm_set_native_mode - * Set adm channel native mode. * If enabled matrix mixer will be * running in native mode for channel * configuration for this device session. * */ void adm_set_native_mode(int mode) { this_adm.native_mode = mode; pr_debug("%s: enable native_mode :%d\n", __func__, this_adm.native_mode); } EXPORT_SYMBOL(adm_set_native_mode); /** * adm_close - * command to close ADM copp * * @port_id: Port ID number * @perf_mode: performance mode like LL/ULL/.. * @copp_idx: copp index assigned * * Returns 0 on success or error on failure */ int adm_close(int port_id, int perf_mode, int copp_idx) { struct apr_hdr close; int ret = 0, port_idx; int copp_id = RESET_COPP_ID; pr_info("%s: port_id=0x%x perf_mode: %d copp_idx: %d\n", __func__, port_id, perf_mode, copp_idx); port_id = q6audio_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); return -EINVAL; } if ((copp_idx < 0) || (copp_idx >= MAX_COPPS_PER_PORT)) { pr_err("%s: Invalid copp idx: %d\n", __func__, copp_idx); return -EINVAL; } port_channel_map[port_idx].set_channel_map = false; if (this_adm.copp.adm_delay[port_idx][copp_idx] && perf_mode == LEGACY_PCM_MODE) { atomic_set(&this_adm.copp.adm_delay_stat[port_idx][copp_idx], 1); this_adm.copp.adm_delay[port_idx][copp_idx] = 0; wake_up(&this_adm.copp.adm_delay_wait[port_idx][copp_idx]); } atomic_dec(&this_adm.copp.cnt[port_idx][copp_idx]); if (!(atomic_read(&this_adm.copp.cnt[port_idx][copp_idx]))) { copp_id = adm_get_copp_id(port_idx, copp_idx); pr_debug("%s: Closing ADM port_idx:%d copp_idx:%d copp_id:0x%x\n", __func__, port_idx, copp_idx, copp_id); if ((!perf_mode) && (this_adm.outband_memmap.paddr != 0) && (atomic_read(&this_adm.copp.topology[port_idx][copp_idx]) == SRS_TRUMEDIA_TOPOLOGY_ID)) { atomic_set(&this_adm.mem_map_index, ADM_SRS_TRUMEDIA); ret = adm_memory_unmap_regions(); if (ret < 0) { pr_err("%s: adm mem unmmap err %d", __func__, ret); } else { atomic_set(&this_adm.mem_map_handles [ADM_SRS_TRUMEDIA], 0); } } if ((afe_get_port_type(port_id) == MSM_AFE_PORT_TYPE_TX) && this_adm.sourceTrackingData.memmap.paddr) { atomic_set(&this_adm.mem_map_index, ADM_MEM_MAP_INDEX_SOURCE_TRACKING); ret = adm_memory_unmap_regions(); if (ret < 0) { pr_err("%s: adm mem unmmap err %d", __func__, ret); } msm_audio_ion_free( this_adm.sourceTrackingData.dma_buf); this_adm.sourceTrackingData.dma_buf = NULL; this_adm.sourceTrackingData.memmap.size = 0; this_adm.sourceTrackingData.memmap.kvaddr = NULL; this_adm.sourceTrackingData.memmap.paddr = 0; this_adm.sourceTrackingData.apr_cmd_status = -1; atomic_set(&this_adm.mem_map_handles[ ADM_MEM_MAP_INDEX_SOURCE_TRACKING], 0); } close.hdr_field = APR_HDR_FIELD(APR_MSG_TYPE_SEQ_CMD, APR_HDR_LEN(APR_HDR_SIZE), APR_PKT_VER); close.pkt_size = sizeof(close); close.src_svc = APR_SVC_ADM; close.src_domain = APR_DOMAIN_APPS; close.src_port = port_id; close.dest_svc = APR_SVC_ADM; close.dest_domain = APR_DOMAIN_ADSP; close.dest_port = copp_id; close.token = port_idx << 16 | copp_idx; close.opcode = ADM_CMD_DEVICE_CLOSE_V5; atomic_set(&this_adm.copp.id[port_idx][copp_idx], RESET_COPP_ID); atomic_set(&this_adm.copp.cnt[port_idx][copp_idx], 0); atomic_set(&this_adm.copp.topology[port_idx][copp_idx], 0); atomic_set(&this_adm.copp.mode[port_idx][copp_idx], 0); atomic_set(&this_adm.copp.stat[port_idx][copp_idx], -1); atomic_set(&this_adm.copp.rate[port_idx][copp_idx], 0); atomic_set(&this_adm.copp.channels[port_idx][copp_idx], 0); atomic_set(&this_adm.copp.bit_width[port_idx][copp_idx], 0); atomic_set(&this_adm.copp.app_type[port_idx][copp_idx], 0); clear_bit(ADM_STATUS_CALIBRATION_REQUIRED, (void *)&this_adm.copp.adm_status[port_idx][copp_idx]); ret = apr_send_pkt(this_adm.apr, (uint32_t *)&close); if (ret < 0) { pr_err("%s: ADM close failed %d\n", __func__, ret); return -EINVAL; } ret = wait_event_timeout(this_adm.copp.wait[port_idx][copp_idx], atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) >= 0, msecs_to_jiffies(TIMEOUT_MS)); if (!ret) { pr_err("%s: ADM cmd Route timedout for port 0x%x\n", __func__, port_id); return -EINVAL; } else if (atomic_read(&this_adm.copp.stat [port_idx][copp_idx]) > 0) { pr_err("%s: DSP returned error[%s]\n", __func__, adsp_err_get_err_str( atomic_read(&this_adm.copp.stat [port_idx][copp_idx]))); return adsp_err_get_lnx_err_code( atomic_read(&this_adm.copp.stat [port_idx][copp_idx])); } } if (perf_mode != ULTRA_LOW_LATENCY_PCM_MODE) { pr_debug("%s: remove adm device from rtac\n", __func__); rtac_remove_adm_device(port_id, copp_id); } if (port_id == this_adm.ffecns_port_id) this_adm.ffecns_port_id = -1; return 0; } EXPORT_SYMBOL(adm_close); int send_rtac_audvol_cal(void) { int ret = 0; int ret2 = 0; int i = 0; int copp_idx, port_idx, acdb_id, app_id, path; struct cal_block_data *cal_block = NULL; struct audio_cal_info_audvol *audvol_cal_info = NULL; struct rtac_adm rtac_adm_data; mutex_lock(&this_adm.cal_data[ADM_RTAC_AUDVOL_CAL]->lock); cal_block = cal_utils_get_only_cal_block( this_adm.cal_data[ADM_RTAC_AUDVOL_CAL]); if (cal_block == NULL || cal_utils_is_cal_stale(cal_block)) { pr_err("%s: can't find cal block!\n", __func__); goto unlock; } audvol_cal_info = cal_block->cal_info; if (audvol_cal_info == NULL) { pr_err("%s: audvol_cal_info is NULL!\n", __func__); goto unlock; } get_rtac_adm_data(&rtac_adm_data); for (; i < rtac_adm_data.num_of_dev; i++) { acdb_id = rtac_adm_data.device[i].acdb_dev_id; if (acdb_id == 0) acdb_id = audvol_cal_info->acdb_id; app_id = rtac_adm_data.device[i].app_type; if (app_id == 0) app_id = audvol_cal_info->app_type; path = afe_get_port_type(rtac_adm_data.device[i].afe_port); if ((acdb_id == audvol_cal_info->acdb_id) && (app_id == audvol_cal_info->app_type) && (path == audvol_cal_info->path)) { if (adm_get_indexes_from_copp_id(rtac_adm_data. device[i].copp, &copp_idx, &port_idx) != 0) { pr_debug("%s: Copp Id %d is not active\n", __func__, rtac_adm_data.device[i].copp); continue; } ret2 = adm_remap_and_send_cal_block(ADM_RTAC_AUDVOL_CAL, rtac_adm_data.device[i].afe_port, copp_idx, cal_block, atomic_read(&this_adm.copp. mode[port_idx][copp_idx]), audvol_cal_info->app_type, audvol_cal_info->acdb_id, atomic_read(&this_adm.copp. rate[port_idx][copp_idx])); if (ret2 < 0) { pr_debug("%s: remap and send failed for copp Id %d, acdb id %d, app type %d, path %d\n", __func__, rtac_adm_data.device[i].copp, audvol_cal_info->acdb_id, audvol_cal_info->app_type, audvol_cal_info->path); ret = ret2; } } } unlock: mutex_unlock(&this_adm.cal_data[ADM_RTAC_AUDVOL_CAL]->lock); return ret; } int adm_map_rtac_block(struct rtac_cal_block_data *cal_block) { int result = 0; pr_debug("%s:\n", __func__); if (cal_block == NULL) { pr_err("%s: cal_block is NULL!\n", __func__); result = -EINVAL; goto done; } if (cal_block->cal_data.paddr == 0) { pr_debug("%s: No address to map!\n", __func__); result = -EINVAL; goto done; } if (cal_block->map_data.map_size == 0) { pr_debug("%s: map size is 0!\n", __func__); result = -EINVAL; goto done; } /* valid port ID needed for callback use primary I2S */ atomic_set(&this_adm.mem_map_index, ADM_RTAC_APR_CAL); result = adm_memory_map_regions(&cal_block->cal_data.paddr, 0, &cal_block->map_data.map_size, 1); if (result < 0) { pr_err("%s: RTAC mmap did not work! size = %d result %d\n", __func__, cal_block->map_data.map_size, result); pr_debug("%s: RTAC mmap did not work! addr = 0x%pK, size = %d\n", __func__, &cal_block->cal_data.paddr, cal_block->map_data.map_size); goto done; } cal_block->map_data.map_handle = atomic_read( &this_adm.mem_map_handles[ADM_RTAC_APR_CAL]); done: return result; } int adm_unmap_rtac_block(uint32_t *mem_map_handle) { int result = 0; pr_debug("%s:\n", __func__); if (mem_map_handle == NULL) { pr_debug("%s: Map handle is NULL, nothing to unmap\n", __func__); goto done; } if (*mem_map_handle == 0) { pr_debug("%s: Map handle is 0, nothing to unmap\n", __func__); goto done; } if (*mem_map_handle != atomic_read( &this_adm.mem_map_handles[ADM_RTAC_APR_CAL])) { pr_err("%s: Map handles do not match! Unmapping RTAC, RTAC map 0x%x, ADM map 0x%x\n", __func__, *mem_map_handle, atomic_read( &this_adm.mem_map_handles[ADM_RTAC_APR_CAL])); /* if mismatch use handle passed in to unmap */ atomic_set(&this_adm.mem_map_handles[ADM_RTAC_APR_CAL], *mem_map_handle); } /* valid port ID needed for callback use primary I2S */ atomic_set(&this_adm.mem_map_index, ADM_RTAC_APR_CAL); result = adm_memory_unmap_regions(); if (result < 0) { pr_debug("%s: adm_memory_unmap_regions failed, error %d\n", __func__, result); } else { atomic_set(&this_adm.mem_map_handles[ADM_RTAC_APR_CAL], 0); *mem_map_handle = 0; } done: return result; } static int get_cal_type_index(int32_t cal_type) { int ret = -EINVAL; switch (cal_type) { case ADM_AUDPROC_CAL_TYPE: ret = ADM_AUDPROC_CAL; break; case ADM_LSM_AUDPROC_CAL_TYPE: ret = ADM_LSM_AUDPROC_CAL; break; case ADM_AUDVOL_CAL_TYPE: ret = ADM_AUDVOL_CAL; break; case ADM_CUST_TOPOLOGY_CAL_TYPE: ret = ADM_CUSTOM_TOP_CAL; break; case ADM_RTAC_INFO_CAL_TYPE: ret = ADM_RTAC_INFO_CAL; break; case ADM_RTAC_APR_CAL_TYPE: ret = ADM_RTAC_APR_CAL; break; case ADM_RTAC_AUDVOL_CAL_TYPE: ret = ADM_RTAC_AUDVOL_CAL; break; case ADM_LSM_AUDPROC_PERSISTENT_CAL_TYPE: ret = ADM_LSM_AUDPROC_PERSISTENT_CAL; break; default: pr_err("%s: invalid cal type %d!\n", __func__, cal_type); } return ret; } static int adm_alloc_cal(int32_t cal_type, size_t data_size, void *data) { int ret = 0; int cal_index; pr_debug("%s:\n", __func__); cal_index = get_cal_type_index(cal_type); if (cal_index < 0) { pr_err("%s: could not get cal index %d!\n", __func__, cal_index); ret = -EINVAL; goto done; } ret = cal_utils_alloc_cal(data_size, data, this_adm.cal_data[cal_index], 0, NULL); if (ret < 0) { pr_err("%s: cal_utils_alloc_block failed, ret = %d, cal type = %d!\n", __func__, ret, cal_type); ret = -EINVAL; goto done; } done: return ret; } static int adm_dealloc_cal(int32_t cal_type, size_t data_size, void *data) { int ret = 0; int cal_index; pr_debug("%s:\n", __func__); cal_index = get_cal_type_index(cal_type); if (cal_index < 0) { pr_err("%s: could not get cal index %d!\n", __func__, cal_index); ret = -EINVAL; goto done; } ret = cal_utils_dealloc_cal(data_size, data, this_adm.cal_data[cal_index]); if (ret < 0) { pr_err("%s: cal_utils_dealloc_block failed, ret = %d, cal type = %d!\n", __func__, ret, cal_type); ret = -EINVAL; goto done; } done: return ret; } static int adm_set_cal(int32_t cal_type, size_t data_size, void *data) { int ret = 0; int cal_index; pr_debug("%s:\n", __func__); cal_index = get_cal_type_index(cal_type); if (cal_index < 0) { pr_err("%s: could not get cal index %d!\n", __func__, cal_index); ret = -EINVAL; goto done; } ret = cal_utils_set_cal(data_size, data, this_adm.cal_data[cal_index], 0, NULL); if (ret < 0) { pr_err("%s: cal_utils_set_cal failed, ret = %d, cal type = %d!\n", __func__, ret, cal_type); ret = -EINVAL; goto done; } if (cal_index == ADM_CUSTOM_TOP_CAL) { mutex_lock(&this_adm.cal_data[ADM_CUSTOM_TOP_CAL]->lock); this_adm.set_custom_topology = 1; mutex_unlock(&this_adm.cal_data[ADM_CUSTOM_TOP_CAL]->lock); } else if (cal_index == ADM_RTAC_AUDVOL_CAL) { send_rtac_audvol_cal(); } done: return ret; } static int adm_map_cal_data(int32_t cal_type, struct cal_block_data *cal_block) { int ret = 0; int cal_index; pr_debug("%s:\n", __func__); cal_index = get_cal_type_index(cal_type); if (cal_index < 0) { pr_err("%s: could not get cal index %d!\n", __func__, cal_index); ret = -EINVAL; goto done; } atomic_set(&this_adm.mem_map_index, cal_index); ret = adm_memory_map_regions(&cal_block->cal_data.paddr, 0, (uint32_t *)&cal_block->map_data.map_size, 1); if (ret < 0) { pr_err("%s: map did not work! cal_type %i ret %d\n", __func__, cal_index, ret); ret = -ENODEV; goto done; } cal_block->map_data.q6map_handle = atomic_read(&this_adm. mem_map_handles[cal_index]); done: return ret; } static int adm_unmap_cal_data(int32_t cal_type, struct cal_block_data *cal_block) { int ret = 0; int cal_index; pr_debug("%s:\n", __func__); cal_index = get_cal_type_index(cal_type); if (cal_index < 0) { pr_err("%s: could not get cal index %d!\n", __func__, cal_index); ret = -EINVAL; goto done; } if (cal_block == NULL) { pr_err("%s: Cal block is NULL!\n", __func__); goto done; } if (cal_block->map_data.q6map_handle == 0) { pr_err("%s: Map handle is NULL, nothing to unmap\n", __func__); goto done; } atomic_set(&this_adm.mem_map_handles[cal_index], cal_block->map_data.q6map_handle); atomic_set(&this_adm.mem_map_index, cal_index); ret = adm_memory_unmap_regions(); if (ret < 0) { pr_err("%s: unmap did not work! cal_type %i ret %d\n", __func__, cal_index, ret); ret = -ENODEV; goto done; } cal_block->map_data.q6map_handle = 0; done: return ret; } static void adm_delete_cal_data(void) { pr_debug("%s:\n", __func__); cal_utils_destroy_cal_types(ADM_MAX_CAL_TYPES, this_adm.cal_data); } static int adm_init_cal_data(void) { int ret = 0; struct cal_type_info cal_type_info[] = { {{ADM_CUST_TOPOLOGY_CAL_TYPE, {adm_alloc_cal, adm_dealloc_cal, NULL, adm_set_cal, NULL, NULL} }, {adm_map_cal_data, adm_unmap_cal_data, cal_utils_match_buf_num} }, {{ADM_AUDPROC_CAL_TYPE, {adm_alloc_cal, adm_dealloc_cal, NULL, adm_set_cal, NULL, NULL} }, {adm_map_cal_data, adm_unmap_cal_data, cal_utils_match_buf_num} }, {{ADM_LSM_AUDPROC_CAL_TYPE, {adm_alloc_cal, adm_dealloc_cal, NULL, adm_set_cal, NULL, NULL} }, {adm_map_cal_data, adm_unmap_cal_data, cal_utils_match_buf_num} }, {{ADM_AUDVOL_CAL_TYPE, {adm_alloc_cal, adm_dealloc_cal, NULL, adm_set_cal, NULL, NULL} }, {adm_map_cal_data, adm_unmap_cal_data, cal_utils_match_buf_num} }, {{ADM_RTAC_INFO_CAL_TYPE, {NULL, NULL, NULL, NULL, NULL, NULL} }, {NULL, NULL, cal_utils_match_buf_num} }, {{ADM_RTAC_APR_CAL_TYPE, {NULL, NULL, NULL, NULL, NULL, NULL} }, {NULL, NULL, cal_utils_match_buf_num} }, {{SRS_TRUMEDIA_CAL_TYPE, {NULL, NULL, NULL, NULL, NULL, NULL} }, {NULL, NULL, cal_utils_match_buf_num} }, {{ADM_RTAC_AUDVOL_CAL_TYPE, {adm_alloc_cal, adm_dealloc_cal, NULL, adm_set_cal, NULL, NULL} }, {adm_map_cal_data, adm_unmap_cal_data, cal_utils_match_buf_num} }, {{ADM_LSM_AUDPROC_PERSISTENT_CAL_TYPE, {adm_alloc_cal, adm_dealloc_cal, NULL, adm_set_cal, NULL, NULL} }, {adm_map_cal_data, adm_unmap_cal_data, cal_utils_match_buf_num} }, }; pr_debug("%s:\n", __func__); ret = cal_utils_create_cal_types(ADM_MAX_CAL_TYPES, this_adm.cal_data, cal_type_info); if (ret < 0) { pr_err("%s: could not create cal type! ret %d\n", __func__, ret); ret = -EINVAL; goto err; } return ret; err: adm_delete_cal_data(); return ret; } /** * adm_set_volume - * command to set volume on ADM copp * * @port_id: Port ID number * @copp_idx: copp index assigned * @volume: gain value to set * * Returns 0 on success or error on failure */ int adm_set_volume(int port_id, int copp_idx, int volume) { struct audproc_volume_ctrl_master_gain audproc_vol; struct param_hdr_v3 param_hdr; int rc = 0; pr_debug("%s: port_id %d, volume %d\n", __func__, port_id, volume); memset(&audproc_vol, 0, sizeof(audproc_vol)); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = AUDPROC_MODULE_ID_VOL_CTRL; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = AUDPROC_PARAM_ID_VOL_CTRL_MASTER_GAIN; param_hdr.param_size = sizeof(audproc_vol); audproc_vol.master_gain = volume; rc = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &audproc_vol); if (rc) pr_err("%s: Failed to set volume, err %d\n", __func__, rc); return rc; } EXPORT_SYMBOL(adm_set_volume); /** * adm_set_softvolume - * command to set softvolume * * @port_id: Port ID number * @copp_idx: copp index assigned * @softvol_param: Params to set for softvolume * * Returns 0 on success or error on failure */ int adm_set_softvolume(int port_id, int copp_idx, struct audproc_softvolume_params *softvol_param) { struct audproc_soft_step_volume_params audproc_softvol; struct param_hdr_v3 param_hdr; int rc = 0; pr_debug("%s: period %d step %d curve %d\n", __func__, softvol_param->period, softvol_param->step, softvol_param->rampingcurve); memset(&audproc_softvol, 0, sizeof(audproc_softvol)); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = AUDPROC_MODULE_ID_VOL_CTRL; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = AUDPROC_PARAM_ID_SOFT_VOL_STEPPING_PARAMETERS; param_hdr.param_size = sizeof(audproc_softvol); audproc_softvol.period = softvol_param->period; audproc_softvol.step = softvol_param->step; audproc_softvol.ramping_curve = softvol_param->rampingcurve; pr_debug("%s: period %d, step %d, curve %d\n", __func__, audproc_softvol.period, audproc_softvol.step, audproc_softvol.ramping_curve); rc = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &audproc_softvol); if (rc) pr_err("%s: Failed to set soft volume, err %d\n", __func__, rc); return rc; } EXPORT_SYMBOL(adm_set_softvolume); /** * adm_set_mic_gain - * command to set MIC gain * * @port_id: Port ID number * @copp_idx: copp index assigned * @volume: gain value to set * * Returns 0 on success or error on failure */ int adm_set_mic_gain(int port_id, int copp_idx, int volume) { struct admx_mic_gain mic_gain_params; struct param_hdr_v3 param_hdr; int rc = 0; pr_debug("%s: Setting mic gain to %d at port_id 0x%x\n", __func__, volume, port_id); memset(&mic_gain_params, 0, sizeof(mic_gain_params)); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = ADM_MODULE_IDX_MIC_GAIN_CTRL; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = ADM_PARAM_IDX_MIC_GAIN; param_hdr.param_size = sizeof(mic_gain_params); mic_gain_params.tx_mic_gain = volume; rc = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &mic_gain_params); if (rc) pr_err("%s: Failed to set mic gain, err %d\n", __func__, rc); return rc; } EXPORT_SYMBOL(adm_set_mic_gain); /** * adm_send_set_multichannel_ec_primary_mic_ch - * command to set multi-ch EC primary mic * * @port_id: Port ID number * @copp_idx: copp index assigned * @primary_mic_ch: channel number of primary mic * * Returns 0 on success or error on failure */ int adm_send_set_multichannel_ec_primary_mic_ch(int port_id, int copp_idx, int primary_mic_ch) { struct admx_sec_primary_mic_ch sec_primary_ch_params; struct param_hdr_v3 param_hdr; int rc = 0; pr_debug("%s port_id 0x%x, copp_idx 0x%x, primary_mic_ch %d\n", __func__, port_id, copp_idx, primary_mic_ch); memset(&sec_primary_ch_params, 0, sizeof(sec_primary_ch_params)); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = AUDPROC_MODULE_ID_VOICE_TX_SECNS; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = AUDPROC_PARAM_IDX_SEC_PRIMARY_MIC_CH; param_hdr.param_size = sizeof(sec_primary_ch_params); sec_primary_ch_params.version = 0; sec_primary_ch_params.sec_primary_mic_ch = primary_mic_ch; rc = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &sec_primary_ch_params); if (rc) pr_err("%s: Failed to set primary mic chanel, err %d\n", __func__, rc); return rc; } EXPORT_SYMBOL(adm_send_set_multichannel_ec_primary_mic_ch); /** * adm_set_ffecns_effect - * command to set effect for ffecns module * * @effect: effect payload * * Returns 0 on success or error on failure */ int adm_set_ffecns_effect(int effect) { struct ffecns_effect ffecns_params; struct param_hdr_v3 param_hdr; int rc = 0; int copp_idx = 0; copp_idx = adm_get_default_copp_idx(this_adm.ffecns_port_id); if ((copp_idx < 0) || (copp_idx >= MAX_COPPS_PER_PORT)) { pr_err("%s, no active copp to query rms copp_idx:%d\n", __func__, copp_idx); return -EINVAL; } memset(&ffecns_params, 0, sizeof(ffecns_params)); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = FFECNS_MODULE_ID; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = FLUENCE_CMN_GLOBAL_EFFECT_PARAM_ID; param_hdr.param_size = sizeof(ffecns_params); ffecns_params.payload = effect; rc = adm_pack_and_set_one_pp_param(this_adm.ffecns_port_id, copp_idx, param_hdr, (uint8_t *) &ffecns_params); if (rc) pr_err("%s: Failed to set ffecns effect, err %d\n", __func__, rc); return rc; } EXPORT_SYMBOL(adm_set_ffecns_effect); /** * adm_param_enable - * command to send params to ADM for given module * * @port_id: Port ID number * @copp_idx: copp index assigned * @module_id: ADM module * @enable: flag to enable or disable module * * Returns 0 on success or error on failure */ int adm_param_enable(int port_id, int copp_idx, int module_id, int enable) { struct module_instance_info mod_inst_info; memset(&mod_inst_info, 0, sizeof(mod_inst_info)); mod_inst_info.module_id = module_id; mod_inst_info.instance_id = INSTANCE_ID_0; return adm_param_enable_v2(port_id, copp_idx, mod_inst_info, enable); } EXPORT_SYMBOL(adm_param_enable); /** * adm_param_enable_v2 - * command to send params to ADM for given module * * @port_id: Port ID number * @copp_idx: copp index assigned * @mod_inst_info: module and instance ID info * @enable: flag to enable or disable module * * Returns 0 on success or error on failure */ int adm_param_enable_v2(int port_id, int copp_idx, struct module_instance_info mod_inst_info, int enable) { uint32_t enable_param; struct param_hdr_v3 param_hdr; int rc = 0; if (enable < 0 || enable > 1) { pr_err("%s: Invalid value for enable %d\n", __func__, enable); return -EINVAL; } pr_debug("%s port_id %d, module_id 0x%x, instance_id 0x%x, enable %d\n", __func__, port_id, mod_inst_info.module_id, mod_inst_info.instance_id, enable); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = mod_inst_info.module_id; param_hdr.instance_id = mod_inst_info.instance_id; param_hdr.param_id = AUDPROC_PARAM_ID_ENABLE; param_hdr.param_size = sizeof(enable_param); enable_param = enable; rc = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &enable_param); if (rc) pr_err("%s: Failed to set enable of module(%d) instance(%d) to %d, err %d\n", __func__, mod_inst_info.module_id, mod_inst_info.instance_id, enable, rc); return rc; } EXPORT_SYMBOL(adm_param_enable_v2); /** * adm_send_calibration - * send ADM calibration to DSP * * @port_id: Port ID number * @copp_idx: copp index assigned * @path: direction or ADM path type * @perf_mode: performance mode like LL/ULL/.. * @cal_type: calibration type to use * @params: pointer with cal data * @size: cal size * * Returns 0 on success or error on failure */ int adm_send_calibration(int port_id, int copp_idx, int path, int perf_mode, int cal_type, char *params, int size) { int rc = 0; pr_debug("%s:port_id %d, path %d, perf_mode %d, cal_type %d, size %d\n", __func__, port_id, path, perf_mode, cal_type, size); /* Maps audio_dev_ctrl path definition to ACDB definition */ if (get_cal_path(path) != RX_DEVICE) { pr_err("%s: acdb_path %d\n", __func__, path); rc = -EINVAL; goto end; } rc = adm_set_pp_params(port_id, copp_idx, NULL, (u8 *) params, size); end: return rc; } EXPORT_SYMBOL(adm_send_calibration); /* * adm_update_wait_parameters must be called with routing driver locks. * adm_reset_wait_parameters must be called with routing driver locks. * set and reset parmeters are separated to make sure it is always called * under routing driver lock. * adm_wait_timeout is to block until timeout or interrupted. Timeout is * not a an error. */ int adm_set_wait_parameters(int port_id, int copp_idx) { int ret = 0, port_idx; pr_debug("%s: port_id 0x%x, copp_idx %d\n", __func__, port_id, copp_idx); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id %#x\n", __func__, port_id); ret = -EINVAL; goto end; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_num: %d\n", __func__, copp_idx); return -EINVAL; } this_adm.copp.adm_delay[port_idx][copp_idx] = 1; atomic_set(&this_adm.copp.adm_delay_stat[port_idx][copp_idx], 0); end: return ret; } EXPORT_SYMBOL(adm_set_wait_parameters); /** * adm_reset_wait_parameters - * reset wait parameters or ADM delay value * * @port_id: Port ID number * @copp_idx: copp index assigned * * Returns 0 on success or error on failure */ int adm_reset_wait_parameters(int port_id, int copp_idx) { int ret = 0, port_idx; pr_debug("%s: port_id 0x%x copp_idx %d\n", __func__, port_id, copp_idx); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id %#x\n", __func__, port_id); ret = -EINVAL; goto end; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_num: %d\n", __func__, copp_idx); return -EINVAL; } atomic_set(&this_adm.copp.adm_delay_stat[port_idx][copp_idx], 1); this_adm.copp.adm_delay[port_idx][copp_idx] = 0; end: return ret; } EXPORT_SYMBOL(adm_reset_wait_parameters); /** * adm_wait_timeout - * ADM wait command after command send to DSP * * @port_id: Port ID number * @copp_idx: copp index assigned * @wait_time: value in ms for command timeout * * Returns 0 on success or error on failure */ int adm_wait_timeout(int port_id, int copp_idx, int wait_time) { int ret = 0, port_idx; pr_debug("%s: port_id 0x%x, copp_idx %d, wait_time %d\n", __func__, port_id, copp_idx, wait_time); port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id %#x\n", __func__, port_id); ret = -EINVAL; goto end; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_num: %d\n", __func__, copp_idx); return -EINVAL; } ret = wait_event_timeout( this_adm.copp.adm_delay_wait[port_idx][copp_idx], atomic_read(&this_adm.copp.adm_delay_stat[port_idx][copp_idx]), msecs_to_jiffies(wait_time)); pr_debug("%s: return %d\n", __func__, ret); if (ret != 0) ret = -EINTR; end: pr_debug("%s: return %d--\n", __func__, ret); return ret; } EXPORT_SYMBOL(adm_wait_timeout); /** * adm_store_cal_data - * Retrieve calibration data for ADM copp device * * @port_id: Port ID number * @copp_idx: copp index assigned * @path: direction or copp type * @perf_mode: performance mode like LL/ULL/.. * @cal_index: calibration index to use * @params: pointer to store cal data * @size: pointer to fill with cal size * * Returns 0 on success or error on failure */ int adm_store_cal_data(int port_id, int copp_idx, int path, int perf_mode, int cal_index, char *params, int *size) { int rc = 0; struct cal_block_data *cal_block = NULL; int app_type, acdb_id, port_idx, sample_rate; if (this_adm.cal_data[cal_index] == NULL) { pr_debug("%s: cal_index %d not allocated!\n", __func__, cal_index); goto end; } if (get_cal_path(path) != RX_DEVICE) { pr_debug("%s: Invalid path to store calibration %d\n", __func__, path); rc = -EINVAL; goto end; } port_id = afe_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0) { pr_err("%s: Invalid port_id 0x%x\n", __func__, port_id); rc = -EINVAL; goto end; } if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_num: %d\n", __func__, copp_idx); return -EINVAL; } acdb_id = atomic_read(&this_adm.copp.acdb_id[port_idx][copp_idx]); app_type = atomic_read(&this_adm.copp.app_type[port_idx][copp_idx]); sample_rate = atomic_read(&this_adm.copp.rate[port_idx][copp_idx]); mutex_lock(&this_adm.cal_data[cal_index]->lock); cal_block = adm_find_cal(cal_index, get_cal_path(path), app_type, acdb_id, sample_rate); if (cal_block == NULL) goto unlock; if (cal_block->cal_data.size <= 0) { pr_debug("%s: No ADM cal send for port_id = 0x%x!\n", __func__, port_id); rc = -EINVAL; goto unlock; } if (cal_index == ADM_AUDPROC_CAL || cal_index == ADM_LSM_AUDPROC_CAL) { if (cal_block->cal_data.size > AUD_PROC_BLOCK_SIZE) { pr_err("%s:audproc:invalid size exp/actual[%zd, %d]\n", __func__, cal_block->cal_data.size, *size); rc = -ENOMEM; goto unlock; } } else if (cal_index == ADM_LSM_AUDPROC_PERSISTENT_CAL) { if (cal_block->cal_data.size > AUD_PROC_PERSIST_BLOCK_SIZE) { pr_err("%s:persist invalid size exp/actual[%zd, %d]\n", __func__, cal_block->cal_data.size, *size); rc = -ENOMEM; goto unlock; } } else if (cal_index == ADM_AUDVOL_CAL) { if (cal_block->cal_data.size > AUD_VOL_BLOCK_SIZE) { pr_err("%s:aud_vol:invalid size exp/actual[%zd, %d]\n", __func__, cal_block->cal_data.size, *size); rc = -ENOMEM; goto unlock; } } else { pr_debug("%s: Not valid calibration for dolby topolgy\n", __func__); rc = -EINVAL; goto unlock; } memcpy(params, cal_block->cal_data.kvaddr, cal_block->cal_data.size); *size = cal_block->cal_data.size; pr_debug("%s:port_id %d, copp_idx %d, path %d", __func__, port_id, copp_idx, path); pr_debug("perf_mode %d, cal_type %d, size %d\n", perf_mode, cal_index, *size); unlock: mutex_unlock(&this_adm.cal_data[cal_index]->lock); end: return rc; } EXPORT_SYMBOL(adm_store_cal_data); /** * adm_send_compressed_device_mute - * command to send mute for compressed device * * @port_id: Port ID number * @copp_idx: copp index assigned * @mute_on: flag to indicate mute or unmute * * Returns 0 on success or error on failure */ int adm_send_compressed_device_mute(int port_id, int copp_idx, bool mute_on) { u32 mute_param = mute_on ? 1 : 0; struct param_hdr_v3 param_hdr; int ret = 0; pr_debug("%s port_id: 0x%x, copp_idx %d, mute_on: %d\n", __func__, port_id, copp_idx, mute_on); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = AUDPROC_MODULE_ID_COMPRESSED_MUTE; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = AUDPROC_PARAM_ID_COMPRESSED_MUTE; param_hdr.param_size = sizeof(mute_param); ret = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &mute_param); if (ret) pr_err("%s: Failed to set mute, err %d\n", __func__, ret); return ret; } EXPORT_SYMBOL(adm_send_compressed_device_mute); /** * adm_send_compressed_device_latency - * command to send latency for compressed device * * @port_id: Port ID number * @copp_idx: copp index assigned * @latency: latency value to pass * * Returns 0 on success or error on failure */ int adm_send_compressed_device_latency(int port_id, int copp_idx, int latency) { u32 latency_param; struct param_hdr_v3 param_hdr; int ret = 0; pr_debug("%s port_id: 0x%x, copp_idx %d latency: %d\n", __func__, port_id, copp_idx, latency); if (latency < 0) { pr_err("%s: Invalid value for latency %d", __func__, latency); return -EINVAL; } memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = AUDPROC_MODULE_ID_COMPRESSED_LATENCY; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = AUDPROC_PARAM_ID_COMPRESSED_LATENCY; param_hdr.param_size = sizeof(latency_param); latency_param = latency; ret = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &latency_param); if (ret) pr_err("%s: Failed to set latency, err %d\n", __func__, ret); return ret; } EXPORT_SYMBOL(adm_send_compressed_device_latency); /** * adm_swap_speaker_channels * * Receives port_id, copp_idx, sample rate, spk_swap and * send MFC command to swap speaker channel. * Return zero on success. On failure returns nonzero. * * port_id - Passed value, port_id for which channels swap is wanted * copp_idx - Passed value, copp_idx for which channels swap is wanted * sample_rate - Passed value, sample rate used by app type config * spk_swap - Passed value, spk_swap for check if swap flag is set */ int adm_swap_speaker_channels(int port_id, int copp_idx, int sample_rate, bool spk_swap) { struct audproc_mfc_param_media_fmt mfc_cfg; struct param_hdr_v3 param_hdr; uint16_t num_channels; int port_idx = 0; int ret = 0; pr_debug("%s: Enter, port_id %d, copp_idx %d\n", __func__, port_id, copp_idx); port_id = q6audio_convert_virtual_to_portid(port_id); port_idx = adm_validate_and_get_port_index(port_id); if (port_idx < 0 || port_idx >= AFE_MAX_PORTS) { pr_err("%s: Invalid port_id %#x\n", __func__, port_id); return -EINVAL; } else if (copp_idx < 0 || copp_idx >= MAX_COPPS_PER_PORT) { pr_err("%s: Invalid copp_idx 0x%x\n", __func__, copp_idx); return -EINVAL; } num_channels = atomic_read(&this_adm.copp.channels[port_idx][copp_idx]); if (num_channels != 2) { pr_debug("%s: Invalid number of channels: %d\n", __func__, num_channels); return -EINVAL; } memset(&mfc_cfg, 0, sizeof(mfc_cfg)); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = AUDPROC_MODULE_ID_MFC; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = AUDPROC_PARAM_ID_MFC_OUTPUT_MEDIA_FORMAT; param_hdr.param_size = sizeof(mfc_cfg); mfc_cfg.sampling_rate = sample_rate; mfc_cfg.bits_per_sample = atomic_read(&this_adm.copp.bit_width[port_idx][copp_idx]); mfc_cfg.num_channels = num_channels; /* Currently applying speaker swap for only 2 channel use case */ if (spk_swap) { mfc_cfg.channel_type[0] = (uint16_t) PCM_CHANNEL_FR; mfc_cfg.channel_type[1] = (uint16_t) PCM_CHANNEL_FL; } else { mfc_cfg.channel_type[0] = (uint16_t) PCM_CHANNEL_FL; mfc_cfg.channel_type[1] = (uint16_t) PCM_CHANNEL_FR; } ret = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (u8 *) &mfc_cfg); if (ret < 0) { pr_err("%s: Failed to set swap speaker channels on port[0x%x] failed %d\n", __func__, port_id, ret); return ret; } pr_debug("%s: mfc_cfg Set params returned success", __func__); return 0; } EXPORT_SYMBOL(adm_swap_speaker_channels); /** * adm_set_sound_focus - * Update sound focus info * * @port_id: Port ID number * @copp_idx: copp index assigned * @soundFocusData: sound focus data to pass * * Returns 0 on success or error on failure */ int adm_set_sound_focus(int port_id, int copp_idx, struct sound_focus_param soundFocusData) { struct adm_param_fluence_soundfocus_t soundfocus_params; struct param_hdr_v3 param_hdr; int ret = 0; int i; pr_debug("%s: Enter, port_id %d, copp_idx %d\n", __func__, port_id, copp_idx); memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = VOICEPROC_MODULE_ID_FLUENCE_PRO_VC_TX; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = VOICEPROC_PARAM_ID_FLUENCE_SOUNDFOCUS; param_hdr.param_size = sizeof(soundfocus_params); memset(&(soundfocus_params), 0xFF, sizeof(soundfocus_params)); for (i = 0; i < MAX_SECTORS; i++) { soundfocus_params.start_angles[i] = soundFocusData.start_angle[i]; soundfocus_params.enables[i] = soundFocusData.enable[i]; pr_debug("%s: start_angle[%d] = %d\n", __func__, i, soundFocusData.start_angle[i]); pr_debug("%s: enable[%d] = %d\n", __func__, i, soundFocusData.enable[i]); } soundfocus_params.gain_step = soundFocusData.gain_step; pr_debug("%s: gain_step = %d\n", __func__, soundFocusData.gain_step); soundfocus_params.reserved = 0; ret = adm_pack_and_set_one_pp_param(port_id, copp_idx, param_hdr, (uint8_t *) &soundfocus_params); if (ret) pr_err("%s: Failed to set sound focus params, err %d\n", __func__, ret); pr_debug("%s: Exit, ret=%d\n", __func__, ret); return ret; } EXPORT_SYMBOL(adm_set_sound_focus); /** * adm_get_sound_focus - * Retrieve sound focus info * * @port_id: Port ID number * @copp_idx: copp index assigned * @soundFocusData: pointer for sound focus data to be updated with * * Returns 0 on success or error on failure */ int adm_get_sound_focus(int port_id, int copp_idx, struct sound_focus_param *soundFocusData) { int ret = 0, i; char *params_value; uint32_t max_param_size = 0; struct adm_param_fluence_soundfocus_t *soundfocus_params = NULL; struct param_hdr_v3 param_hdr; pr_debug("%s: Enter, port_id %d, copp_idx %d\n", __func__, port_id, copp_idx); max_param_size = sizeof(struct adm_param_fluence_soundfocus_t) + sizeof(union param_hdrs); params_value = kzalloc(max_param_size, GFP_KERNEL); if (!params_value) return -ENOMEM; memset(¶m_hdr, 0, sizeof(param_hdr)); param_hdr.module_id = VOICEPROC_MODULE_ID_FLUENCE_PRO_VC_TX; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = VOICEPROC_PARAM_ID_FLUENCE_SOUNDFOCUS; param_hdr.param_size = max_param_size; ret = adm_get_pp_params(port_id, copp_idx, ADM_CLIENT_ID_SOURCE_TRACKING, NULL, ¶m_hdr, params_value); if (ret) { pr_err("%s: get parameters failed ret:%d\n", __func__, ret); ret = -EINVAL; goto done; } if (this_adm.sourceTrackingData.apr_cmd_status != 0) { pr_err("%s - get params returned error [%s]\n", __func__, adsp_err_get_err_str( this_adm.sourceTrackingData.apr_cmd_status)); ret = adsp_err_get_lnx_err_code( this_adm.sourceTrackingData.apr_cmd_status); goto done; } soundfocus_params = (struct adm_param_fluence_soundfocus_t *) params_value; for (i = 0; i < MAX_SECTORS; i++) { soundFocusData->start_angle[i] = soundfocus_params->start_angles[i]; soundFocusData->enable[i] = soundfocus_params->enables[i]; pr_debug("%s: start_angle[%d] = %d\n", __func__, i, soundFocusData->start_angle[i]); pr_debug("%s: enable[%d] = %d\n", __func__, i, soundFocusData->enable[i]); } soundFocusData->gain_step = soundfocus_params->gain_step; pr_debug("%s: gain_step = %d\n", __func__, soundFocusData->gain_step); done: pr_debug("%s: Exit, ret = %d\n", __func__, ret); kfree(params_value); return ret; } EXPORT_SYMBOL(adm_get_sound_focus); static int adm_source_tracking_alloc_map_memory(void) { int ret; pr_debug("%s: Enter\n", __func__); ret = msm_audio_ion_alloc(&this_adm.sourceTrackingData.dma_buf, AUD_PROC_BLOCK_SIZE, &this_adm.sourceTrackingData.memmap.paddr, &this_adm.sourceTrackingData.memmap.size, &this_adm.sourceTrackingData.memmap.kvaddr); if (ret) { pr_err("%s: failed to allocate memory\n", __func__); ret = -EINVAL; goto done; } atomic_set(&this_adm.mem_map_index, ADM_MEM_MAP_INDEX_SOURCE_TRACKING); ret = adm_memory_map_regions(&this_adm.sourceTrackingData.memmap.paddr, 0, (uint32_t *)&this_adm.sourceTrackingData.memmap.size, 1); if (ret < 0) { pr_err("%s: failed to map memory, paddr = 0x%pK, size = %d\n", __func__, (void *)this_adm.sourceTrackingData.memmap.paddr, (uint32_t)this_adm.sourceTrackingData.memmap.size); msm_audio_ion_free(this_adm.sourceTrackingData.dma_buf); this_adm.sourceTrackingData.dma_buf = NULL; this_adm.sourceTrackingData.memmap.size = 0; this_adm.sourceTrackingData.memmap.kvaddr = NULL; this_adm.sourceTrackingData.memmap.paddr = 0; this_adm.sourceTrackingData.apr_cmd_status = -1; atomic_set(&this_adm.mem_map_handles [ADM_MEM_MAP_INDEX_SOURCE_TRACKING], 0); ret = -EINVAL; goto done; } ret = 0; pr_debug("%s: paddr = 0x%pK, size = %d, mem_map_handle = 0x%x\n", __func__, (void *)this_adm.sourceTrackingData.memmap.paddr, (uint32_t)this_adm.sourceTrackingData.memmap.size, atomic_read(&this_adm.mem_map_handles [ADM_MEM_MAP_INDEX_SOURCE_TRACKING])); done: pr_debug("%s: Exit, ret = %d\n", __func__, ret); return ret; } /** * adm_get_source_tracking - * Retrieve source tracking info * * @port_id: Port ID number * @copp_idx: copp index assigned * @sourceTrackingData: pointer for source track data to be updated with * * Returns 0 on success or error on failure */ int adm_get_source_tracking(int port_id, int copp_idx, struct source_tracking_param *sourceTrackingData) { struct adm_param_fluence_sourcetracking_t *source_tracking_params = NULL; struct mem_mapping_hdr mem_hdr; struct param_hdr_v3 param_hdr; int i = 0; int ret = 0; pr_debug("%s: Enter, port_id %d, copp_idx %d\n", __func__, port_id, copp_idx); if (!this_adm.sourceTrackingData.memmap.paddr) { /* Allocate and map shared memory for out of band usage */ ret = adm_source_tracking_alloc_map_memory(); if (ret != 0) { ret = -EINVAL; goto done; } } memset(&mem_hdr, 0, sizeof(mem_hdr)); memset(¶m_hdr, 0, sizeof(param_hdr)); mem_hdr.data_payload_addr_lsw = lower_32_bits(this_adm.sourceTrackingData.memmap.paddr); mem_hdr.data_payload_addr_msw = msm_audio_populate_upper_32_bits( this_adm.sourceTrackingData.memmap.paddr); mem_hdr.mem_map_handle = atomic_read( &this_adm.mem_map_handles[ADM_MEM_MAP_INDEX_SOURCE_TRACKING]); param_hdr.module_id = VOICEPROC_MODULE_ID_FLUENCE_PRO_VC_TX; param_hdr.instance_id = INSTANCE_ID_0; param_hdr.param_id = VOICEPROC_PARAM_ID_FLUENCE_SOURCETRACKING; /* * This size should be the max size of the calibration data + header. * Use the union size to ensure max size is used. */ param_hdr.param_size = sizeof(struct adm_param_fluence_sourcetracking_t) + sizeof(struct param_hdr_v3); /* * Retrieving parameters out of band, so no need to provide a buffer for * the returned parameter data as it will be at the memory location * provided. */ ret = adm_get_pp_params(port_id, copp_idx, ADM_CLIENT_ID_SOURCE_TRACKING, &mem_hdr, ¶m_hdr, NULL); if (ret) { pr_err("%s: Failed to get params, error %d\n", __func__, ret); goto done; } if (this_adm.sourceTrackingData.apr_cmd_status != 0) { pr_err("%s - get params returned error [%s]\n", __func__, adsp_err_get_err_str( this_adm.sourceTrackingData.apr_cmd_status)); ret = adsp_err_get_lnx_err_code( this_adm.sourceTrackingData.apr_cmd_status); goto done; } /* How do we know what the param data was retrieved with for hdr size */ source_tracking_params = (struct adm_param_fluence_sourcetracking_t *) (this_adm.sourceTrackingData.memmap.kvaddr + sizeof(struct param_hdr_v3)); for (i = 0; i < MAX_SECTORS; i++) { sourceTrackingData->vad[i] = source_tracking_params->vad[i]; pr_debug("%s: vad[%d] = %d\n", __func__, i, sourceTrackingData->vad[i]); } sourceTrackingData->doa_speech = source_tracking_params->doa_speech; pr_debug("%s: doa_speech = %d\n", __func__, sourceTrackingData->doa_speech); for (i = 0; i < MAX_NOISE_SOURCE_INDICATORS; i++) { sourceTrackingData->doa_noise[i] = source_tracking_params->doa_noise[i]; pr_debug("%s: doa_noise[%d] = %d\n", __func__, i, sourceTrackingData->doa_noise[i]); } for (i = 0; i < MAX_POLAR_ACTIVITY_INDICATORS; i++) { sourceTrackingData->polar_activity[i] = source_tracking_params->polar_activity[i]; pr_debug("%s: polar_activity[%d] = %d\n", __func__, i, sourceTrackingData->polar_activity[i]); } ret = 0; done: pr_debug("%s: Exit, ret=%d\n", __func__, ret); return ret; } EXPORT_SYMBOL(adm_get_source_tracking); int __init adm_init(void) { int i = 0, j; this_adm.ec_ref_rx = -1; this_adm.ffecns_port_id = -1; init_waitqueue_head(&this_adm.matrix_map_wait); init_waitqueue_head(&this_adm.adm_wait); for (i = 0; i < AFE_MAX_PORTS; i++) { for (j = 0; j < MAX_COPPS_PER_PORT; j++) { atomic_set(&this_adm.copp.id[i][j], RESET_COPP_ID); init_waitqueue_head(&this_adm.copp.wait[i][j]); init_waitqueue_head( &this_adm.copp.adm_delay_wait[i][j]); } } if (adm_init_cal_data()) pr_err("%s: could not init cal data!\n", __func__); this_adm.sourceTrackingData.dma_buf = NULL; this_adm.sourceTrackingData.memmap.size = 0; this_adm.sourceTrackingData.memmap.kvaddr = NULL; this_adm.sourceTrackingData.memmap.paddr = 0; this_adm.sourceTrackingData.apr_cmd_status = -1; return 0; } void adm_exit(void) { if (this_adm.apr) adm_reset_data(); adm_delete_cal_data(); }